Spore: Difference between revisions

From Wikipedia, the free encyclopedia
Jump to navigation Jump to search
VisualWikitext
imported>OAbot
m Open access bot: url-access updated in citation with #oabot.
 
imported>Maxeto0910
no sentences
 
(2 intermediate revisions by 2 users not shown)
Line 2: Line 2:
{{about|spores in eukaryotes|bacterial spores|endospore|other uses}}
{{about|spores in eukaryotes|bacterial spores|endospore|other uses}}
{{Use dmy dates|date=July 2020}}
{{Use dmy dates|date=July 2020}}
[[Image:Sporic meiosis.svg|thumb|300px|Spores produced in a sporic life cycle.]]
[[Image:Sporic meiosis.svg|thumb|300px|Spores produced in a sporic life cycle]]
[[Image:Brachythecium rutabulum on Populus x canadensis.jpg|thumb|300px|Fresh snow partially covers rough-stalked feather-moss ''([[Bryopsida|Brachythecium rutabulum]])'', growing on a [[thinning|thinned]] hybrid black poplar ''([[populus|Populus x canadensis]])''. The last stage of the [[moss#Life cycle|moss lifecycle]] is shown, where the [[sporophyte]]s are visible before dispersion of their spores: the [[calyptra]] ('''1''') is still attached to the [[sporangium|capsule]] ('''3'''). The tops of the [[gametophytes]] ('''2''') can be discerned as well. Inset shows the surrounding, black poplars growing on sandy [[loam]] on the bank of a [[bog pond|kolk]], with the detail area marked.]]
[[Image:Brachythecium rutabulum on Populus x canadensis.jpg|thumb|300px|Fresh snow partially covers rough-stalked feather-moss ''([[Bryopsida|Brachythecium rutabulum]])'', growing on a [[thinning|thinned]] hybrid black poplar ''([[populus|Populus x canadensis]])''. The last stage of the [[moss#Life cycle|moss lifecycle]] is shown, where the [[sporophyte]]s are visible before dispersion of their spores: the [[calyptra]] ('''1''') is still attached to the [[sporangium|capsule]] ('''3'''). The tops of the [[gametophytes]] ('''2''') can be discerned as well. Inset shows the surrounding, black poplars growing on sandy [[loam]] on the bank of a [[bog pond|kolk]], with the detail area marked.]]


In [[biology]], a '''spore''' is a unit of [[sexual reproduction|sexual]] (in fungi) or [[asexual reproduction]] that may be adapted for [[biological dispersal|dispersal]] and for survival, often for extended periods of time, in unfavourable conditions.<ref>{{Citation |last1=Setlow |first1=Peter |title=Spores and Their Significance |date=2014-04-30 |url=http://doi.wiley.com/10.1128/9781555818463.ch3 |work=Food Microbiology |pages=45–79 |editor-last=Doyle |editor-first=Michael P. |access-date=2023-12-13 |place=Washington, DC, USA |publisher=ASM Press |language=en |doi=10.1128/9781555818463.ch3 |isbn=978-1-68367-058-2 |last2=Johnson |first2=Eric A. |editor2-last=Buchanan |editor2-first=Robert L.|url-access=subscription }}</ref> Spores form part of the [[Biological life cycle|life cycles]] of many [[plant]]s, [[algae]], [[fungus|fungi]] and [[protozoa]].<ref>{{Cite web |url=http://tolweb.org/tree/home.pages/searchresults.html?cx=009557456284541951685%3A50nf_5tpvuq&cof=FORID%3A9&ie=UTF-8&q=spore&sa=Search |title=Tree of Life Web Project |access-date=5 February 2018 |archive-url=https://web.archive.org/web/20180205184645/http://tolweb.org/tree/home.pages/searchresults.html?cx=009557456284541951685%3A50nf_5tpvuq&cof=FORID%3A9&ie=UTF-8&q=spore&sa=Search |archive-date=5 February 2018 |url-status=dead }}</ref> They were thought to have appeared as early as the mid-late [[Ordovician]] period as an adaptation of early land plants.<ref name="Wellman-2000b">{{Cite journal |last1=Wellman |first1=C. H. |last2=Gray |first2=J. |date=2000-06-29 |title=The microfossil record of early land plants |journal=Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences |volume=355 |issue=1398 |pages=717–731; discussion 731–732 |doi=10.1098/rstb.2000.0612 |issn=0962-8436 |pmc=1692785 |pmid=10905606}}</ref>
In [[biology]], a '''spore''' is a unit of [[sexual reproduction|sexual]] (in fungi) or [[asexual reproduction]] that may be adapted for [[biological dispersal|dispersal]] and for survival, often for extended periods of time, in unfavourable conditions.<ref>{{cite book |last1=Setlow |first1=Peter |last2=Johnson |first2=Eric A. |title=Food Microbiology |chapter=Spores and Their Significance |date=2014 |pages=45–79 |doi=10.1128/9781555818463.ch3 |isbn=978-1-68367-058-2 }}</ref> Spores form part of the [[Biological life cycle|life cycles]] of many [[plant]]s, [[algae]], [[fungus|fungi]] and [[protozoa]].<ref>{{Cite web |url=http://tolweb.org/tree/home.pages/searchresults.html?cx=009557456284541951685%3A50nf_5tpvuq&cof=FORID%3A9&ie=UTF-8&q=spore&sa=Search |title=Tree of Life Web Project |access-date=5 February 2018 |archive-url=https://web.archive.org/web/20180205184645/http://tolweb.org/tree/home.pages/searchresults.html?cx=009557456284541951685%3A50nf_5tpvuq&cof=FORID%3A9&ie=UTF-8&q=spore&sa=Search |archive-date=5 February 2018 |url-status=dead }}</ref> They were thought to have appeared as early as the mid-late [[Ordovician]] period as an adaptation of early land plants.<ref name="Wellman-2000b">{{Cite journal |last1=Wellman |first1=C. H. |last2=Gray |first2=J. |date=2000-06-29 |title=The microfossil record of early land plants |journal=Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences |volume=355 |issue=1398 |pages=717–731; discussion 731–732 |doi=10.1098/rstb.2000.0612 |issn=0962-8436 |pmc=1692785 |pmid=10905606}}</ref>


[[Bacterial spore]]s are not part of a sexual cycle, but are resistant structures used for survival under unfavourable conditions.<ref>{{Cite book |last=Abel-Santos |first=Ernesto |title=Bacterial spores: current research and applications |date=2012 |publisher=Caister academic press |isbn=978-1-908230-00-3 |location=Norfolk}}</ref> [[Myxozoa]]n spores release amoeboid infectious germs ("amoebulae") into their hosts for parasitic infection, but also reproduce within the hosts through the pairing of two nuclei within the plasmodium, which develops from the amoebula.<ref>{{cite web|url=http://tolweb.org/Myxozoa/2460 |title=Myxozoa|archiveurl=https://web.archive.org/web/20150216140158/http://tolweb.org/Myxozoa/2460|archivedate=16 February 2015|work=Tree of Life Web Project|author=Ivan Fiala|date=10 July 2008|accessdate=14 January 2014|quote=Myxospores consist of several cells, which are transformed to shell valves, nematocyst-like polar capsules with coiled extrudible polar filaments and amoeboid infective germs.}}</ref>
[[Bacterial spore]]s are not part of a sexual cycle, but are resistant structures used for survival under unfavourable conditions.<ref>{{Cite book |last=Abel-Santos |first=Ernesto |title=Bacterial spores: current research and applications |date=2012 |publisher=Caister academic press |isbn=978-1-908230-00-3 |location=Norfolk}}{{pn|date=August 2025}}</ref> [[Myxozoa]]n spores release amoeboid infectious germs ("amoebulae") into their hosts for parasitic infection, but also reproduce within the hosts through the pairing of two nuclei within the plasmodium, which develops from the amoebula.<ref>{{cite web|url=http://tolweb.org/Myxozoa/2460 |title=Myxozoa|archiveurl=https://web.archive.org/web/20150216140158/http://tolweb.org/Myxozoa/2460|archivedate=16 February 2015|work=Tree of Life Web Project|author=Ivan Fiala|date=10 July 2008|accessdate=14 January 2014|quote=Myxospores consist of several cells, which are transformed to shell valves, nematocyst-like polar capsules with coiled extrudible polar filaments and amoeboid infective germs.}}</ref>


In plants, spores are usually [[haploid]] and [[unicellular]] and are produced by [[meiosis]] in the [[sporangium]] of a [[diploid]] [[sporophyte]]. In some rare cases, a diploid spore is also produced in some algae, or fungi.<ref>{{Cite web |title=Diploid Spore - an overview {{!}} ScienceDirect Topics |url=https://www.sciencedirect.com/topics/biochemistry-genetics-and-molecular-biology/diploid-spore |access-date=2023-12-13 |website=www.sciencedirect.com |archive-date=13 December 2023 |archive-url=https://web.archive.org/web/20231213180708/https://www.sciencedirect.com/topics/biochemistry-genetics-and-molecular-biology/diploid-spore |url-status=live }}</ref> Under favourable conditions, the spore can develop into a new [[organism]] using [[mitosis|mitotic]] division, producing a [[multicellular]] [[gametophyte]], which eventually goes on to produce gametes. Two gametes fuse to form a [[zygote]], which develops into a new sporophyte. This cycle is known as [[alternation of generations]].
In plants, spores are usually [[haploid]] and [[unicellular]] and are produced by [[meiosis]] in the [[sporangium]] of a [[diploid]] [[sporophyte]]. In some rare cases, a diploid spore is also produced in some algae, or fungi.{{fact|date=August 2025}} Under favourable conditions, the spore can develop into a new [[organism]] using [[mitosis|mitotic]] division, producing a [[multicellular]] [[gametophyte]], which eventually goes on to produce gametes. Two gametes fuse to form a [[zygote]], which develops into a new sporophyte. This cycle is known as [[alternation of generations]].


The spores of [[seed plant]]s are produced internally, and the megaspores (formed within the ovules) and the microspores are involved in the formation of more complex structures that form the dispersal units, the [[seed]]s and [[pollen]] grains.
The spores of [[seed plant]]s are produced internally, and the megaspores (formed within the ovules) and the microspores are involved in the formation of more complex structures that form the dispersal units, the [[seed]]s and [[pollen]] grains.


==Definition==
==Definition==
The term ''spore'' derives from the [[ancient Greek]] word σπορά ''spora'', meaning "[[seed]], sowing", related to σπόρος ''{{lang|grc-Latn|sporos}}'', "sowing", and σπείρειν ''{{lang|grc-Latn|speirein}}'', "to sow".
The term ''spore'' derives from [[Greek language|Greek]] {{lang|grc|σπορά}}, {{Transliteration|grc|spora}}, meaning '[[seed]], sowing', related to {{lang|grc|σπόρος}}, {{Transliteration|grc|sporos}}, 'sowing', and {{Transliteration|grc|speirein}}, 'to sow'.<ref>{{cite web |title=Spore - Etymology, Origin & Meaning |url=https://www.etymonline.com/word/spore |website=Online Etymology Dictionary |access-date=14 August 2025}}</ref><ref>{{cite web |title=Sparse - Etymology, Origin & Meaning |url=https://www.etymonline.com/word/sparse |website=Online Etymology Dictionary |access-date=14 August 2025}}</ref>


In common parlance, the difference between a "spore" and a "[[gamete]]" is that a spore will germinate and develop into a [[sporeling]], while a gamete needs to combine with another gamete to form a zygote before developing further.
In common parlance, the difference between a "spore" and a "[[gamete]]" is that a spore will germinate and develop into a [[sporeling]], while a gamete needs to combine with another gamete to form a zygote before developing further.{{cn|date=June 2025}}


The main difference between spores and seeds as [[Biological dispersal|dispersal units]] is that spores are unicellular, the first cell of a gametophyte, while seeds contain within them a developing embryo (the multicellular sporophyte of the next generation), produced by the fusion of the male gamete of the pollen tube with the female gamete formed by the megagametophyte within the ovule. Spores germinate to give rise to haploid gametophytes, while seeds germinate to give rise to diploid sporophytes.
The main difference between spores and seeds as [[Biological dispersal|dispersal units]] is that spores are unicellular, the first cell of a gametophyte, while seeds contain within them a developing embryo (the multicellular sporophyte of the next generation), produced by the fusion of the male gamete of the pollen tube with the female gamete formed by the megagametophyte within the ovule. Spores germinate to give rise to haploid gametophytes, while seeds germinate to give rise to diploid sporophytes.{{cn|date=June 2025}}


==Classification of spore-producing organisms==
==Classification of spore-producing organisms==
Line 24: Line 24:


===Plants===
===Plants===
[[Vascular plant]] spores are always [[haploid]]. Vascular plants are either '''homosporous''' (also known as '''isosporous''') or '''[[Heterospory|heterosporous]]'''. Plants that are homosporous produce spores of the same size and type.
[[Vascular plant]] spores are always [[haploid]]. Vascular plants are either '''homosporous''' (also known as '''isosporous''') or '''[[Heterospory|heterosporous]]'''. Plants that are homosporous produce spores of the same size and type.<ref>{{Cite web |date=2025-08-05 |title=Plant - Homosporous, Life, Histories {{!}} Britannica |url=https://www.britannica.com/plant/plant/Homosporous-life-histories |access-date=2025-08-08 |website=www.britannica.com |language=en}}</ref>


Heterosporous plants, such as [[seed plant]]s, [[spikemoss]]es, [[Isoëtes|quillworts]], and [[fern]]s of the order [[Salviniales]] produce spores of two different sizes: the larger spore (megaspore) in effect functioning as a "female" spore and the smaller (microspore) functioning as a "male". Such plants typically give rise to the two kind of spores from within separate sporangia, either a '''megasporangium''' that produces megaspores or a '''microsporangium''' that produces microspores. In flowering plants, these sporangia occur within the carpel and anthers, respectively.
Heterosporous plants, such as [[seed plant]]s, [[spikemoss]]es, [[Isoëtes|quillworts]], and [[fern]]s of the order [[Salviniales]] produce spores of two different sizes: the larger spore (megaspore) in effect functioning as a "female" spore and the smaller (microspore) functioning as a "male".{{fact|date=August 2025}} Such plants typically give rise to the two kind of spores from within separate sporangia, either a '''megasporangium''' that produces megaspores or a '''microsporangium''' that produces microspores. In flowering plants, these sporangia occur within the carpel and anthers, respectively.<ref>{{Cite web |last=Jerrett |first=Adrianne |date=30 September 2021 |title=What Is The Function Of The Anther On A Flower? |url=https://www.sciencing.com/what-is-the-function-of-the-anther-on-a-flower-12521584/ |access-date=2025-08-08 |website=Sciencing |language=en-US}}</ref>


===Fungi===
===Fungi===
Line 32: Line 32:


==Classification of spores==
==Classification of spores==
Spores can be classified in several ways such as by their spore producing structure, function, origin during life cycle, and mobility.
Spores can be classified in several ways such as by their spore producing structure, function, origin during life cycle, and mobility.{{cn|date=June 2025}}


Below is a table listing the mode of classification, name, identifying characteristic, examples, and images of different spore species.
Below is a table listing the mode of classification, name, identifying characteristic, examples, and images of different spore species.
Line 96: Line 96:
| colspan="2" |[[Chlamydospore|Chalmydospore]]
| colspan="2" |[[Chlamydospore|Chalmydospore]]
|Thick-walled [[resting spore]]s of fungi produced to survive in unfavorable conditions
|Thick-walled [[resting spore]]s of fungi produced to survive in unfavorable conditions
|[[Ascomycota|Asomycota]]
|[[Ascomycota|Ascomycota]]
|[[File:Candida_pseudohyphae,_chlamydospores,_blastospores.png|thumb|[[Hypha|Pseudohyphae]], chlamydospores and [[blastospore]]s of [[Candida (fungus)|''Candida'' yeast]].]]
|[[File:Candida_pseudohyphae,_chlamydospores,_blastospores.png|thumb|[[Hypha|Pseudohyphae]], chlamydospores and [[blastospore]]s of [[Candida (fungus)|''Candida'' yeast]]]]
|-
|-
| rowspan="2" |Parasitic Fungal Spore
| rowspan="2" |Parasitic Fungal Spore
Line 189: Line 189:
  | pmc = 1692785
  | pmc = 1692785
}}</ref>
}}</ref>
Individual trilete spores resembling those of modern [[cryptogam]]ic plants first appeared in the fossil record at the end of the Ordovician period.<ref name="SteemansHerisse2009">{{cite journal|last1=Steemans|first1=P.|last2=Herisse|first2=A. L.|last3=Melvin|first3=J.|last4=Miller|first4=M. A.|last5=Paris|first5=F.|last6=Verniers|first6=J.|last7=Wellman|first7=C. H.|title=Origin and Radiation of the Earliest Vascular Land Plants|journal=Science|volume=324|issue=5925|year=2009|pages=353|issn=0036-8075|doi=10.1126/science.1169659|bibcode=2009Sci...324..353S|pmid=19372423|s2cid=206518080|url=https://biblio.ugent.be/publication/697223/file/709198.pdf|access-date=1 November 2017|archive-url=https://web.archive.org/web/20170922112350/https://biblio.ugent.be/publication/697223/file/709198.pdf|archive-date=22 September 2017|url-status=live|hdl=1854/LU-697223|hdl-access=free}}</ref>
Individual trilete spores resembling those of modern [[cryptogam]]ic plants first appeared in the fossil record at the end of the Ordovician period.<ref name="SteemansHerisse2009">{{cite journal |last1=Steemans |first1=Philippe |last2=HéRissé |first2=Alain Le |last3=Melvin |first3=John |last4=Miller |first4=Merrell A. |last5=Paris |first5=Florentin |last6=Verniers |first6=Jacques |last7=Wellman |first7=Charles H. |title=Origin and Radiation of the Earliest Vascular Land Plants |journal=Science |date=2009 |volume=324 |issue=5925 |page=353 |doi=10.1126/science.1169659 |pmid=19372423 |bibcode=2009Sci...324..353S |hdl=1854/LU-697223 |hdl-access=free }}</ref>


==Dispersal==
==Dispersal==
[[File:Fungus spore ejection.ogg|thumb|Spores being ejected by fungi.]]
[[File:Fungus spore ejection.ogg|thumb|Spores being ejected by fungi]]


In fungi, both asexual and sexual spores or sporangiospores of many fungal species are actively dispersed by forcible ejection from their reproductive structures. This ejection ensures exit of the spores from the reproductive structures as well as travelling through the air over long distances. Many fungi thereby possess specialized mechanical and physiological mechanisms as well as spore-surface structures, such as [[hydrophobin]]s, for spore ejection. These mechanisms include, for example, forcible discharge of ascospores enabled by the structure of the ascus and accumulation of [[osmolyte]]s in the fluids of the ascus that lead to explosive discharge of the ascospores into the air.<ref name="Trail">{{cite journal|author=Trail F.|year= 2007|title=Fungal cannons: explosive spore discharge in the Ascomycota|journal=FEMS Microbiology Letters|volume=276|pages=12–8|pmid=17784861|doi=10.1111/j.1574-6968.2007.00900.x|issue=1|doi-access=free}}</ref>
In fungi, both asexual and sexual spores or sporangiospores of many fungal species are actively dispersed by forcible ejection from their reproductive structures. This ejection ensures exit of the spores from the reproductive structures as well as travelling through the air over long distances. Many fungi thereby possess specialized mechanical and physiological mechanisms as well as spore-surface structures, such as [[hydrophobin]]s, for spore ejection. These mechanisms include, for example, forcible discharge of ascospores enabled by the structure of the ascus and accumulation of [[osmolyte]]s in the fluids of the ascus that lead to explosive discharge of the ascospores into the air.<ref name="Trail">{{cite journal|author=Trail F.|year= 2007|title=Fungal cannons: explosive spore discharge in the Ascomycota|journal=FEMS Microbiology Letters|volume=276|pages=12–8|pmid=17784861|doi=10.1111/j.1574-6968.2007.00900.x|issue=1|doi-access=free}}</ref>


The forcible discharge of single spores termed ''ballistospores'' involves formation of a small drop of water ([[Buller's drop]]), which upon contact with the spore leads to its projectile release with an initial acceleration of more than 10,000 [[G-force|g]].<ref name="Pringle et al.">{{cite journal|vauthors=Pringle A, Patek SN, Fischer M, Stolze J, Money NP |year= 2005|title=The captured launch of a ballistospore|journal=[[Mycologia]]|volume=97|pages=866–71|pmid=16457355|doi=10.3852/mycologia.97.4.866|issue=4}}</ref> Other fungi rely on alternative mechanisms for spore release, such as external mechanical forces, exemplified by [[puffballs]]. Attracting insects, such as flies, to fruiting structures, by virtue of their having lively colours and a putrid odour, for dispersal of fungal spores is yet another strategy, most prominently used by the [[stinkhorns]].
The forcible discharge of single spores termed ''ballistospores'' involves formation of a small drop of water ([[Buller's drop]]), which upon contact with the spore leads to its projectile release with an initial acceleration of more than 10,000 [[G-force|g]].<ref name="Pringle et al.">{{cite journal|vauthors=Pringle A, Patek SN, Fischer M, Stolze J, Money NP |year= 2005|title=The captured launch of a ballistospore|journal=[[Mycologia]]|volume=97|pages=866–71|pmid=16457355|doi=10.3852/mycologia.97.4.866|issue=4}}</ref> Other fungi rely on alternative mechanisms for spore release, such as external mechanical forces, exemplified by [[puffballs]]. Attracting insects, such as flies, to fruiting structures, by virtue of their having lively colours and a putrid odour, for dispersal of fungal spores is yet another strategy, most prominently used by the [[stinkhorns]].{{cn|date=June 2025}}


In Common Smoothcap moss (''[[Atrichum undulatum]]''), the vibration of sporophyte has been shown to be an important mechanism for spore release.<ref>Johansson, Lönnell, Sundberg and Hylander (2014) Release thresholds for moss spores: the importance of turbulence and sporophyte length. Journal of Ecology, n/a-n/a.</ref>
In Common Smoothcap moss (''[[Atrichum undulatum]]''), the vibration of sporophyte has been shown to be an important mechanism for spore release.<ref>{{cite journal |last1=Johansson |first1=Victor |last2=Lönnell |first2=Niklas |last3=Sundberg |first3=Sebastian |last4=Hylander |first4=Kristoffer |last5=Jongejans |first5=Eelke |title=Release thresholds for moss spores: The importance of turbulence and sporophyte length |journal=Journal of Ecology |date=2014 |volume=102 |issue=3 |pages=721–729 |doi=10.1111/1365-2745.12245 |bibcode=2014JEcol.102..721J }}</ref>


In the case of spore-shedding [[vascular plant]]s such as ferns, wind distribution of very light spores provides great capacity for dispersal. Also, spores are less subject to animal predation than seeds because they contain almost no food reserve; however they are more subject to fungal and bacterial predation. Their chief advantage is that, of all forms of progeny, spores require the least energy and materials to produce.
In the case of spore-shedding [[vascular plant]]s such as ferns, wind distribution of very light spores provides great capacity for dispersal. Also, spores are less subject to animal predation than seeds because they contain almost no food reserve; however they are more subject to fungal and bacterial predation. Their chief advantage is that, of all forms of progeny, spores require the least energy and materials to produce.{{cn|date=June 2025}}


In the spikemoss ''[[Selaginella lepidophylla]]'', dispersal is achieved in part by an unusual type of [[diaspore (botany)|diaspore]], a [[tumbleweed]].<ref>{{cite web| title = False Rose of Jericho – Selaginella lepidophyllaFalse Rose of Jericho – Selaginella lepidophylla| work = Plant- and Flower guide| date = February 2009| url = http://www.plant-and-flower-guide.com/rose-of-jericho.html| access-date = 1 February 2010| archive-url = https://web.archive.org/web/20110715092118/http://www.plant-and-flower-guide.com/rose-of-jericho.html| archive-date = 15 July 2011| url-status = live}}</ref>
In the spikemoss ''[[Selaginella lepidophylla]]'', dispersal is achieved in part by an unusual type of [[diaspore (botany)|diaspore]], a [[tumbleweed]].<ref>{{cite web| title = False Rose of Jericho – Selaginella lepidophyllaFalse Rose of Jericho – Selaginella lepidophylla| work = Plant- and Flower guide| date = February 2009| url = http://www.plant-and-flower-guide.com/rose-of-jericho.html| access-date = 1 February 2010| archive-url = https://web.archive.org/web/20110715092118/http://www.plant-and-flower-guide.com/rose-of-jericho.html| archive-date = 15 July 2011| url-status = live}}</ref>


== Origin ==
== Origin ==
Spores have been found in [[microfossil]]s dating back to the mid-late [[Ordovician]] period.<ref name="Wellman-2000b"/> Two hypothesized initial functions of spores relate to whether they appeared before or after land plants. The heavily studied hypothesis is that spores were an adaptation of early land plant species, such as [[embryophyte]]s, that allowed for plants to easily disperse while adapting to their non-aquatic environment.<ref name="Wellman-2000b" /><ref name="Norem-1958">{{Cite journal |last=Norem |first=W. L. |date=1958 |title=Keys for the Classification of Fossil Spores and Pollen |url=https://www.jstor.org/stable/1300785 |journal=Journal of Paleontology |volume=32 |issue=4 |pages=666–676 |jstor=1300785 |issn=0022-3360}}</ref> This is particularly supported by the observation of a thick spore wall in [[cryptospore]]s. These spore walls would have protected potential offspring from novel weather elements.<ref name="Wellman-2000b" /> The second more recent hypothesis is that spores were an early predecessor of land plants and formed during errors in the [[meiosis]] of [[algae]], a hypothesized early ancestor of land plants.<ref name="Strother-2021">{{Cite journal |last1=Strother |first1=Paul K. |last2=Foster |first2=Clinton |date=2021-08-13 |title=A fossil record of land plant origins from charophyte algae |url=https://www.science.org/doi/10.1126/science.abj2927 |journal=Science |language=en |volume=373 |issue=6556 |pages=792–796 |doi=10.1126/science.abj2927 |pmid=34385396 |bibcode=2021Sci...373..792S |issn=0036-8075|url-access=subscription }}</ref>
Spores have been found in [[microfossil]]s dating back to the mid-late [[Ordovician]] period.<ref name="Wellman-2000b"/> Two hypothesized initial functions of spores relate to whether they appeared before or after land plants. The heavily studied hypothesis is that spores were an adaptation of early land plant species, such as [[embryophyte]]s, that allowed for plants to easily disperse while adapting to their non-aquatic environment.<ref name="Wellman-2000b" /><ref name="Norem-1958">{{Cite journal |last=Norem |first=W. L. |date=1958 |title=Keys for the Classification of Fossil Spores and Pollen |journal=Journal of Paleontology |volume=32 |issue=4 |pages=666–676 |jstor=1300785 }}</ref> This is particularly supported by the observation of a thick spore wall in [[cryptospore]]s. These spore walls would have protected potential offspring from novel weather elements.<ref name="Wellman-2000b" /> The second more recent hypothesis is that spores were an early predecessor of land plants and formed during errors in the [[meiosis]] of [[algae]], a hypothesized early ancestor of land plants.<ref name="Strother-2021">{{cite journal |last1=Strother |first1=Paul K. |last2=Foster |first2=Clinton |title=A fossil record of land plant origins from charophyte algae |journal=Science |date=13 August 2021 |volume=373 |issue=6556 |pages=792–796 |doi=10.1126/science.abj2927 |pmid=34385396 |bibcode=2021Sci...373..792S }}</ref>


Whether spores arose before or after land plants, their contributions to topics in fields like [[paleontology]] and plant [[phylogenetics]] have been useful.<ref name="Strother-2021" /> The spores found in microfossils, also known as cryptospores, are well preserved due to the fixed material they are in as well as how abundant and widespread they were during their respective time periods. These microfossils are especially helpful when studying the early periods of earth as macrofossils such as plants are not common nor well preserved.<ref name="Wellman-2000b" /> Both cryptospores and modern spores have diverse morphology that indicate possible environmental conditions of earlier periods of Earth and evolutionary relationships of plant species.<ref name="Wellman-2000b" /><ref name="Strother-2021" /><ref name="Norem-1958" />
Whether spores arose before or after land plants, their contributions to topics in fields like [[paleontology]] and plant [[phylogenetics]] have been useful.<ref name="Strother-2021" /> The spores found in microfossils, also known as cryptospores, are well preserved due to the fixed material they are in as well as how abundant and widespread they were during their respective time periods. These microfossils are especially helpful when studying the early periods of earth as macrofossils such as plants are not common nor well preserved.<ref name="Wellman-2000b" /> Both cryptospores and modern spores have diverse morphology that indicate possible environmental conditions of earlier periods of Earth and evolutionary relationships of plant species.<ref name="Wellman-2000b" /><ref name="Strother-2021" /><ref name="Norem-1958" />
Line 214: Line 214:
File:Fernspore1.jpg|Dehisced fern sporangia. (microscopic view, no spores are visible)
File:Fernspore1.jpg|Dehisced fern sporangia. (microscopic view, no spores are visible)
File:Botbrush1.jpg|Spores and elaters from a horsetail. (''[[Equisetum]]'', microscopic view)
File:Botbrush1.jpg|Spores and elaters from a horsetail. (''[[Equisetum]]'', microscopic view)
File:Trilete spores.png|Fossil plant spores (''[[Scylaspora]]'') from Silurian deposits of Sweden.
File:Trilete spores.png|Fossil plant spores (''[[Scylaspora]]'') from Silurian deposits of Sweden
File:Unknown fruit mold with spores methylene blue x2000.jpg|Fruit mold with spores and distinguishable cellular growth. (2000x)
File:Unknown fruit mold with spores methylene blue x2000.jpg|Fruit mold with spores and distinguishable cellular growth (2000x)
File:Reticularia olivacea-1.jpg|Spore clusters, formed inside sporangia of the slime mold ''[[Reticularia olivacea]]'', from pine forests of eastern [[Ukraine]].
File:Reticularia olivacea-1.jpg|Spore clusters, formed inside sporangia of the slime mold ''[[Reticularia olivacea]]'', from pine forests of eastern [[Ukraine]]
File:Tubifera dudkae-4.jpg|Internal surface of the [[peridium]] of the slime mold ''Tubifera dudkae'' with spores.
File:Tubifera dudkae-4.jpg|Internal surface of the [[peridium]] of the slime mold ''Tubifera dudkae'' with spores
</gallery>
</gallery>


Latest revision as of 17:59, 7 November 2025

Template:Short description Script error: No such module "about". Template:Use dmy dates

File:Sporic meiosis.svg
Spores produced in a sporic life cycle
File:Brachythecium rutabulum on Populus x canadensis.jpg
Fresh snow partially covers rough-stalked feather-moss (Brachythecium rutabulum), growing on a thinned hybrid black poplar (Populus x canadensis). The last stage of the moss lifecycle is shown, where the sporophytes are visible before dispersion of their spores: the calyptra (1) is still attached to the capsule (3). The tops of the gametophytes (2) can be discerned as well. Inset shows the surrounding, black poplars growing on sandy loam on the bank of a kolk, with the detail area marked.

In biology, a spore is a unit of sexual (in fungi) or asexual reproduction that may be adapted for dispersal and for survival, often for extended periods of time, in unfavourable conditions.[1] Spores form part of the life cycles of many plants, algae, fungi and protozoa.[2] They were thought to have appeared as early as the mid-late Ordovician period as an adaptation of early land plants.[3]

Bacterial spores are not part of a sexual cycle, but are resistant structures used for survival under unfavourable conditions.[4] Myxozoan spores release amoeboid infectious germs ("amoebulae") into their hosts for parasitic infection, but also reproduce within the hosts through the pairing of two nuclei within the plasmodium, which develops from the amoebula.[5]

In plants, spores are usually haploid and unicellular and are produced by meiosis in the sporangium of a diploid sporophyte. In some rare cases, a diploid spore is also produced in some algae, or fungi.Template:Fact Under favourable conditions, the spore can develop into a new organism using mitotic division, producing a multicellular gametophyte, which eventually goes on to produce gametes. Two gametes fuse to form a zygote, which develops into a new sporophyte. This cycle is known as alternation of generations.

The spores of seed plants are produced internally, and the megaspores (formed within the ovules) and the microspores are involved in the formation of more complex structures that form the dispersal units, the seeds and pollen grains.

Definition

The term spore derives from Greek Script error: No such module "Lang"., Template:Transliteration, meaning 'seed, sowing', related to Script error: No such module "Lang"., Template:Transliteration, 'sowing', and Template:Transliteration, 'to sow'.[6][7]

In common parlance, the difference between a "spore" and a "gamete" is that a spore will germinate and develop into a sporeling, while a gamete needs to combine with another gamete to form a zygote before developing further.Script error: No such module "Unsubst".

The main difference between spores and seeds as dispersal units is that spores are unicellular, the first cell of a gametophyte, while seeds contain within them a developing embryo (the multicellular sporophyte of the next generation), produced by the fusion of the male gamete of the pollen tube with the female gamete formed by the megagametophyte within the ovule. Spores germinate to give rise to haploid gametophytes, while seeds germinate to give rise to diploid sporophytes.Script error: No such module "Unsubst".

Classification of spore-producing organisms

Script error: No such module "anchor".

Plants

Vascular plant spores are always haploid. Vascular plants are either homosporous (also known as isosporous) or heterosporous. Plants that are homosporous produce spores of the same size and type.[8]

Heterosporous plants, such as seed plants, spikemosses, quillworts, and ferns of the order Salviniales produce spores of two different sizes: the larger spore (megaspore) in effect functioning as a "female" spore and the smaller (microspore) functioning as a "male".Template:Fact Such plants typically give rise to the two kind of spores from within separate sporangia, either a megasporangium that produces megaspores or a microsporangium that produces microspores. In flowering plants, these sporangia occur within the carpel and anthers, respectively.[9]

Fungi

Fungi commonly produce spores during sexual and asexual reproduction. Spores are usually haploid and grow into mature haploid individuals through mitotic division of cells (Urediniospores and Teliospores among rusts are dikaryotic). Dikaryotic cells result from the fusion of two haploid gamete cells. Among sporogenic dikaryotic cells, karyogamy (the fusion of the two haploid nuclei) occurs to produce a diploid cell. Diploid cells undergo meiosis to produce haploid spores.Script error: No such module "Unsubst".

Classification of spores

Spores can be classified in several ways such as by their spore producing structure, function, origin during life cycle, and mobility.Script error: No such module "Unsubst".

Below is a table listing the mode of classification, name, identifying characteristic, examples, and images of different spore species.

Mode of Classification Name Identifying Characteristic Example Spore Containing Organism Image
Spore Producing Structure Sporangiospore Produced by sporangium Zygomycetes
File:Sporangium of fungi.jpg
Sporangium of Fungi
Zygospores Produced by zygosporangium Zygomycetes
File:Rhizopus zygospores.jpg
Zygospores on Rhizopus
Ascospores Produced by ascus Ascomycetes
File:Bitunicate ascus and ascospores of Didymella rabiei.png
Ascospores of Didymella Rabiei
Basidiospores Produced by basidium Basidiomycetes
File:Basidium schematic.svg
Typical reproductive structure of a basidiomycete, including the basidiospore and basidium
Aecispores Produced by aecium Rusts and Smuts
File:Aecium sp.jpg
Aecia on foliage
Urediniospores Produced by uredinium Rusts and Smuts
File:Puccinia thaliae urediniospores.jpg
Uredinospores
Teliospores Produced by teilum Rusts and Smuts
File:Puccinia helianthi (teliospores).jpg
Microscopic image of teliospores
Oospores Produced by oogonium Oomycetes
File:10554 oospore.jpg
Oospores of Phytophthora agathidicida
Carpospores Produced by carposophorophyte Red Algae
File:Rhod1004.jpg
Light microscopy of Polysiphonia showing a carpospores and carposporophyte inside
Tetraspores Produced by tetrasphorophyte Red Algae
File:Polysiphonia tetraspores WM2.jpg
Tetraspores of Polysiphonia
Function Chalmydospore Thick-walled resting spores of fungi produced to survive in unfavorable conditions Ascomycota
File:Candida pseudohyphae, chlamydospores, blastospores.png
Pseudohyphae, chlamydospores and blastospores of Candida yeast
Parasitic Fungal Spore Internal Spores Germinate within a host
File:Pink fungal parasite on lichen - geograph.org.uk - 1040204.jpg
A parasitic pink fungi on a Lichen tree
External (Environmental) spores Spores released by the host to infest other hosts [10]
Origin During Life Cycle Meiospores Microspores Produced sexually through meiosis, and give rise to a male gametophyte Pollen in seed plants
File:Microspore-formation.svg
In plants, microspores, and in some cases megaspores, are formed from all four products of meiosis.
Megaspores (macrospores) Produced sexually through meiosis, and give rise to a female gametophyte Ovule in seed plants
File:Macrospore-formation.svg
In contrast, in many seed plants and heterosporous ferns, only a single product of meiosis will become a megaspore (macrospore), with the rest degenerating.
Mitospores Produced asexually though mitosis Ascomycetes
File:Morchella conica 1 beentree.jpg
Ascomycete containing mitospores
Mobility Zoospores Mobile through flagella Some algae and fungi
File:Zoospores - Reproductive Structure of the Phytophthora.png
Microscopic image of a Zoospore
Aplanospores Immobile, however still produce flagella
Autospores Immobile spores that do not produce flagella
File:Jenufa SAG 2383.jpg
Autospores of a strain of Jenufa aeroterrestrica
Ballistospores Forcibly discharged from the fungal fruiting body due to internal force (such as built up pressure) Basidiospores and/or part of the genus Pilobus
File:Abb2.5 Fungi Basidiomycota basidium basidiospore ballistospore Bullers drop catapult mechanism 2021 (M. Piepenbring).png
Ballistospore mechanism of dispersal from fungi
Stratismospores Forcibly discharged from the fungal fruting body due to external force (such as raindrops or passing animals) Puffballs
File:Puff Balls - geograph.org.uk - 6255537.jpg
Puff Balls containing Stratismospores

External anatomy

Script error: No such module "anchor".Script error: No such module "anchor".Script error: No such module "anchor".

File:Trilete spores.png
Fossil trilete spores (blue) and a spore tetrad (green) of Late Silurian origin
File:Pollen Ricinus communis sanguineus.jpg
Tricolpate pollen of Ricinus

Under high magnification, spores often have complex patterns or ornamentation on their exterior surfaces. A specialized terminology has been developed to describe features of such patterns. Some markings represent apertures, places where the tough outer coat of the spore can be penetrated when germination occurs. Spores can be categorized based on the position and number of these markings and apertures. Alete spores show no lines. In monolete spores, there is a single narrow line (laesura) on the spore.[11] Indicating the prior contact of two spores that eventually separated.[3] In trilete spores, each spore shows three narrow lines radiating from a center pole.[11] This shows that four spores shared a common origin and were initially in contact with each other forming a tetrahedron.[3] A wider aperture in the shape of a groove may be termed a colpus.[11] The number of colpi distinguishes major groups of plants. Eudicots have tricolpate spores (i.e. spores with three colpi).[12]

Spore tetrads and trilete spores

Script error: No such module "Labelled list hatnote". Envelope-enclosed spore tetrads are taken as the earliest evidence of plant life on land,[13] dating from the mid-Ordovician (early Llanvirn, ~Template:Ma), a period from which no macrofossils have yet been recovered.[14] Individual trilete spores resembling those of modern cryptogamic plants first appeared in the fossil record at the end of the Ordovician period.[15]

Dispersal

File:Fungus spore ejection.ogg
Spores being ejected by fungi

In fungi, both asexual and sexual spores or sporangiospores of many fungal species are actively dispersed by forcible ejection from their reproductive structures. This ejection ensures exit of the spores from the reproductive structures as well as travelling through the air over long distances. Many fungi thereby possess specialized mechanical and physiological mechanisms as well as spore-surface structures, such as hydrophobins, for spore ejection. These mechanisms include, for example, forcible discharge of ascospores enabled by the structure of the ascus and accumulation of osmolytes in the fluids of the ascus that lead to explosive discharge of the ascospores into the air.[16]

The forcible discharge of single spores termed ballistospores involves formation of a small drop of water (Buller's drop), which upon contact with the spore leads to its projectile release with an initial acceleration of more than 10,000 g.[17] Other fungi rely on alternative mechanisms for spore release, such as external mechanical forces, exemplified by puffballs. Attracting insects, such as flies, to fruiting structures, by virtue of their having lively colours and a putrid odour, for dispersal of fungal spores is yet another strategy, most prominently used by the stinkhorns.Script error: No such module "Unsubst".

In Common Smoothcap moss (Atrichum undulatum), the vibration of sporophyte has been shown to be an important mechanism for spore release.[18]

In the case of spore-shedding vascular plants such as ferns, wind distribution of very light spores provides great capacity for dispersal. Also, spores are less subject to animal predation than seeds because they contain almost no food reserve; however they are more subject to fungal and bacterial predation. Their chief advantage is that, of all forms of progeny, spores require the least energy and materials to produce.Script error: No such module "Unsubst".

In the spikemoss Selaginella lepidophylla, dispersal is achieved in part by an unusual type of diaspore, a tumbleweed.[19]

Origin

Spores have been found in microfossils dating back to the mid-late Ordovician period.[3] Two hypothesized initial functions of spores relate to whether they appeared before or after land plants. The heavily studied hypothesis is that spores were an adaptation of early land plant species, such as embryophytes, that allowed for plants to easily disperse while adapting to their non-aquatic environment.[3][20] This is particularly supported by the observation of a thick spore wall in cryptospores. These spore walls would have protected potential offspring from novel weather elements.[3] The second more recent hypothesis is that spores were an early predecessor of land plants and formed during errors in the meiosis of algae, a hypothesized early ancestor of land plants.[21]

Whether spores arose before or after land plants, their contributions to topics in fields like paleontology and plant phylogenetics have been useful.[21] The spores found in microfossils, also known as cryptospores, are well preserved due to the fixed material they are in as well as how abundant and widespread they were during their respective time periods. These microfossils are especially helpful when studying the early periods of earth as macrofossils such as plants are not common nor well preserved.[3] Both cryptospores and modern spores have diverse morphology that indicate possible environmental conditions of earlier periods of Earth and evolutionary relationships of plant species.[3][21][20]

Gallery

See also

Script error: No such module "Portal".

References

Template:Reflist

Template:Botany

Template:Authority control

  1. Script error: No such module "citation/CS1".
  2. Script error: No such module "citation/CS1".
  3. a b c d e f g h Script error: No such module "Citation/CS1".
  4. Script error: No such module "citation/CS1".Template:Pn
  5. Script error: No such module "citation/CS1".
  6. Script error: No such module "citation/CS1".
  7. Script error: No such module "citation/CS1".
  8. Script error: No such module "citation/CS1".
  9. Script error: No such module "citation/CS1".
  10. Script error: No such module "citation/CS1".
  11. a b c Script error: No such module "Citation/CS1".
  12. Script error: No such module "Citation/CS1".
  13. Script error: No such module "Citation/CS1".
  14. Script error: No such module "Citation/CS1".
  15. Script error: No such module "Citation/CS1".
  16. Script error: No such module "Citation/CS1".
  17. Script error: No such module "Citation/CS1".
  18. Script error: No such module "Citation/CS1".
  19. Script error: No such module "citation/CS1".
  20. a b Script error: No such module "Citation/CS1".
  21. a b c Script error: No such module "Citation/CS1".
Retrieved from "http://debianws.lexgopc.com/wiki143/index.php?title=Spore&oldid=3182411"