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{{Short description|Type of chromosome}}

[[File:ChickenChromosomesBMC Genomics5-56Fig4.jpg|right|thumb|200px|Image of [[chicken]] chromosomes featuring the many microchromosomes (appearing as dots). The arrows indicate a stained [[Locus (genetics)|gene locus]] on homologous macrochromosomes.]]
[[File:ChickenChromosomesBMC Genomics5-56Fig4.jpg|right|thumb|200px|Image of [[chicken]] chromosomes featuring the many microchromosomes (appearing as dots). The arrows indicate a stained [[Locus (genetics)|gene locus]] on homologous macrochromosomes.]]


A '''microchromosome''' is a type of very small [[chromosome]] which is a typical component of the [[karyotype]] of [[bird]]s, some [[reptile]]s, [[fish]], and [[amphibian]]s; they tend to{{vague|date=August 2020}} be absent in [[mammals]].<ref name=fillon/> They are less than 20 Mb in size; chromosomes which are greater than 40 [[Megabase|Mb]] in size are known as '''macrochromosomes''', while those between 20 and 40 Mb are classified as '''intermediate chromosomes'''.<ref name=turkey>{{cite journal |last1=Axelsson |first1=Erik |last2=Webster |first2=Matthew T. |last3=Smith |first3=Nick G. C. |last4=Burt |first4=David W. |last5=Ellegren |first5=Hans |title=Comparison of the chicken and turkey genomes reveals a higher rate of nucleotide divergence on microchromosomes than macrochromosomes |journal=Genome Research |volume=15 |issue=1 |pages=120–5 |year=2005 |pmid=15590944 |pmc=540272 |doi=10.1101/gr.3021305}}</ref> Microchromosomes are characteristically very small and often [[cytogenetic]]ally indistinguishable in a [[karyotype]]. While originally thought to be insignificant fragments of chromosomes, in species where they have been studied they have been found to be rich in [[gene]]s. In [[chicken]]s, microchromosomes have been estimated to contain between 50 and 75% of all genes.<ref name=mcqueen/><ref name=evolution/> The presence of microchromosomes makes ordering and identifying chromosomes into a coherent [[karyotype]] particularly difficult. During [[metaphase]], they appear merely as 0.5-1.5 [[μm]] long specks. Their small size and poor condensation into [[heterochromatin]] means they generally lack the diagnostic [[chromosome banding|banding]] patterns and distinct [[centromere]] locations used for chromosome identification.<ref name=fillon/>
A '''microchromosome''' is a [[chromosome]] defined for its relatively small size. They are typical components of the [[karyotype]] of [[bird]]s, some [[reptile]]s, [[fish]], [[amphibian]]s, and [[monotreme]]s.<ref name=ohno1962>{{cite journal |last1=Ohno |first1=Susumu |last2=Christian |first2=L.C. |last3=Stenius |first3=Christina |title=Nucleolus-organizing microchromosomes of Gallus domesticus |journal=Experimental Cell Research |date=September 1962 |volume=27 |issue=3 |pages=612–614 |doi=10.1016/0014-4827(62)90033-2|pmid=13939683 }}</ref> As many bird genomes have chromosomes of widely different lengths, the name was meant to distinguish them from the comparatively large '''macrochromosomes'''.<ref name="gallusgenome">{{cite journal |last1=Hillier |first1=LaDeana W.|last2=International Chicken Genome Sequencing Consortium |title=Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution |journal=Nature |date=December 2004 |volume=432 |issue=7018 |pages=695–716 |doi=10.1038/nature03154|pmid=15592404 |doi-access=free |bibcode=2004Natur.432..695C }}</ref> The distinction referred to the measured size of the chromosome while staining for karyotype, and while there is not a strict definition, chromosomes resembling the large chromosomes of mammals were called '''macrochromosomes''' (roughly 3 to 6&nbsp;μm), while the much smaller ones of less than around 0.5&nbsp;μm were called '''microchromosomes'''.<ref name=Waters21 /> In terms of [[base pair]]s, by convention, those of less than 20Mb were called '''microchromosomes''', those between 20 and 40 Mb are classified as '''intermediate chromosomes''', and those larger than 40Mb are '''macrochromosomes'''.<ref name=turkey>{{cite journal |last1=Axelsson |first1=Erik |last2=Webster |first2=Matthew T. |last3=Smith |first3=Nick G. C. |last4=Burt |first4=David W. |last5=Ellegren |first5=Hans |title=Comparison of the chicken and turkey genomes reveals a higher rate of nucleotide divergence on microchromosomes than macrochromosomes |journal=Genome Research |volume=15 |issue=1 |pages=120–5 |year=2005 |pmid=15590944 |pmc=540272 |doi=10.1101/gr.3021305}}</ref> By this definition, all normal chromosomes in organisms with relatively small genomes (less than 100-200Mb) would be considered microchromosomes.

==Function==
Microchromosomes are characteristically very small and often [[cytogenetic]]ally indistinguishable in a [[karyotype]], which makes ordering and identifying chromosomes into a coherent [[karyotype]] particularly difficult. While originally thought to be insignificant fragments of chromosomes, in species where they have been studied they have been found to be rich in [[gene]]s and high in [[GC content]]. In [[chicken]]s, microchromosomes have been estimated to contain between 50 and 75% of all genes.<ref name=mcqueen/><ref name=evolution/> During [[metaphase]], they appear merely as 0.5-1.5 [[μm]] long specks. Their small size and poor condensation into [[heterochromatin]] means they generally lack the diagnostic [[chromosome banding|banding]] patterns and distinct [[centromere]] locations used for chromosome identification.<ref name=fillon/>

==Occurrence==
Microchromosomes are found in many vertebrates, but not in most mammals.<ref name=ohno1962/> Important comparisons were made using the genomic organization of the [[Florida lancelet]] &ndash; part of a [[sister group]] to all [[vertebrates]] &ndash; suggests that the ancestral [[amniote]] (and vertebrates in general) genome consisted entirely of microchromosomes. Comparison between lancelet and modern vertebrate chromosomes shows that the macrochromosomes were the result of fusion between ancestral microchromosomes. In addition, retention of microchromosomes is shown to be the [[symplesiomorphy|norm]]; the complete loss of them in mammals is the outlier instead.<ref name="Waters21">{{cite journal |last1=Waters |first1=Paul D. |last2=Patel |first2=Hardip R. |last3=Ruiz-Herrera |first3=Aurora |last4=Álvarez-González |first4=Lucía |last5=Lister |first5=Nicholas C. |last6=Simakov |first6=Oleg |last7=Ezaz |first7=Tariq |last8=Kaur |first8=Parwinder |author-link8=Parwinder Kaur |last9=Frere |first9=Celine |last10=Grützner |first10=Frank |last11=Georges |first11=Arthur |last12=Graves |first12=Jennifer A. Marshall |date=9 November 2021 |title=Microchromosomes are building blocks of bird, reptile, and mammal chromosomes |journal=Proceedings of the National Academy of Sciences |volume=118 |issue=45 |pages=e2112494118 |bibcode=2021PNAS..11812494W |doi=10.1073/pnas.2112494118 |pmc=8609325 |pmid=34725164 |doi-access=free}}</ref>

{{cladogram
|title=Relationship among mentioned organisms
|caption=<!-- TODO: color by whether miChrs are present -->
|align=center
|clades=
<!-- Newick string (for easier editing): ([[Lancelet]],([[Garfish]],([[Lungfish]],([[Amphibians]],([[Mammals]],(([[Sqarmates]])[[Lepidosaurs]],([[Turtles]],([[Crocodilians]],[[Birds]])[[Archosaurs]]))[[Reptiles]])[[Amniotes]])[[Tetrapods]]))[[Vertebrates]]) -->
{{clade
|label1=
|1={{clade
|1=[[Lancelet]]
|label2=Vertebrates
|2={{clade
|1=Garfish
|label2=
|2={{clade
|1=Lungfish
|label2=Tetrapods
|2={{clade
|1=Amphibians
|label2=Amniotes
|2={{clade
|1=Mammals
|label2=Reptiles
|2={{clade
|label1=[[Lepidosaurs]]
|1={{clade
|1=[[Squamata]] (snakes, lizards)
}}
|label2=[[Archosauriformes|A[...]formes]]
|2={{clade
|1=Turtles
|label2=[[Archosaurs]]
|2={{clade
|1=[[Crocodilians]]
|2=Birds
}}
}}
}}
}}
}}
}}
}}
}}
}}
}}


==In birds==
==In birds==
Chickens have a [[Ploidy#Diploid|diploid]] number of 78 (2''n'' = 78) chromosomes, and as is usual in birds, the majority are microchromosomes. Classification of chicken chromosomes varies by author. Some classify them as 6 pairs of macrochromosomes, one pair of sex chromosomes, with the remaining 32 pairs being intermediate or microchromosomes.<ref name=mcqueen>{{cite journal |first1=Heather A. |last1=McQueen |first2=Giorgia |last2=Siriaco |first3=Adrian P. |title=Chicken microchromosomes are hyperacetylated, early replicating, and gene rich |journal=Genome Research |volume=8 |issue=6 |pages=621–30 |last3=Bird |year=1998 |pmid=9647637 |pmc=310741 |doi=10.1101/gr.8.6.621}}</ref> Other arrangements such as that used by the International Chicken Genome Sequencing Consortium include five pairs of macrochromosomes, five pairs of intermediate chromosomes, and twenty-eight pairs of microchromosomes.<ref name=turkey/><ref name=genome/> Microchromosomes represent approximately one third of the total genome size, and have been found to have a much higher gene density than macrochromosomes. Because of this, it is estimated that the majority of genes are located on microchromosomes,<ref name=evolution/> though due to the difficulty in physically identifying microchromosomes and the lack of [[Microsatellite (genetics)|microsatellite markers]], it has been difficult to place genes on specific microchromosomes.<ref name=genome/>
Birds (except [[Falconidae]]) usually have karyotypes of approximately 80 chromosomes (''2n = 80''), with only a few being distinguishable macrochromosomes and an average of 60 being microchromosomes.<ref name=fillon/> They are more abundant in birds than any other group of animals. Chickens (''Gallus gallus'') are an important model organism for studying microchromosomes.<ref name=fillon>{{cite journal |last1=Fillon |first1=Valérie |title=The chicken as a model to study microchromosomes in birds: a review |journal=Genetics Selection Evolution |volume=30 |issue=3 |pages=209–19 |year=1998 |doi=10.1186/1297-9686-30-3-209|pmc=2707402 }}</ref> Examination of microchromosomes in birds has led to the hypotheses that they may have originated as conserved fragments of ancestral macrochromosomes, and conversely that macrochromosomes could have arisen as aggregates of microchromosomes.<ref name=fillon/> Comparative [[genomics|genomic]] analysis shows that microchromosomes contain genetic information which has been conserved across multiple classes of chromosomes. This indicates that at least ten chicken microchromosomes arose from fission of larger chromosomes and that the typical bird karyotype arose 100–250 [[mya (unit)|mya]].<ref name=evolution>{{cite journal |last1=Burt |first1=D.W. |title=Origin and evolution of avian microchromosomes |journal=Cytogenetic and Genome Research |volume=96 |issue=1–4 |pages=97–112 |year=2002 |pmid=12438785 |doi=10.1159/000063018|s2cid=26017998 }}</ref>


Birds (except [[Falconidae]]) usually have karyotypes of approximately 80 chromosomes (''2n = 80''), with only a few being distinguishable macrochromosomes and an average of 60 being microchromosomes.<ref name=fillon/> They are more abundant in birds than any other group of animals. Chickens (''Gallus gallus'') are an important model organism for studying microchromosomes.<ref name=fillon>{{cite journal |last1=Fillon |first1=Valérie |title=The chicken as a model to study microchromosomes in birds: a review |journal=Genetics Selection Evolution |volume=30 |issue=3 |pages=209–19 |year=1998 |doi=10.1186/1297-9686-30-3-209 |pmc=2707402 |doi-access=free }}</ref> Examination of microchromosomes in birds has led to the hypotheses that they may have originated as conserved fragments of ancestral macrochromosomes, and conversely that macrochromosomes could have arisen as aggregates of microchromosomes.<ref name=fillon/> Comparative [[genomics|genomic]] analysis shows that microchromosomes contain genetic information which has been conserved across multiple classes of chromosomes. This indicates that at least ten chicken microchromosomes arose from fission of larger chromosomes and that the typical bird karyotype arose 100–250 [[mya (unit)|mya]].<ref name=evolution>{{cite journal |last1=Burt |first1=D.W. |title=Origin and evolution of avian microchromosomes |journal=Cytogenetic and Genome Research |volume=96 |issue=1–4 |pages=97–112 |year=2002 |pmid=12438785 |doi=10.1159/000063018 |s2cid=26017998}}</ref>
===Chickens===
Chickens have a [[Ploidy#Diploid|diploid]] number of 78 (2''n'' = 78) chromosomes, and as is usual in birds, the majority are microchromosomes. Classification of chicken chromosomes varies by author. Some classify them as 6 pairs of macrochromosomes, one pair of sex chromosomes, with the remaining 32 pairs being intermediate or microchromosomes.<ref name=mcqueen>{{cite journal |first1=Heather A. |last1=McQueen |first2=Giorgia |last2=Siriaco |first3=Adrian P. |title=Chicken microchromosomes are hyperacetylated, early replicating, and gene rich |journal=Genome Research |volume=8 |issue=6 |pages=621–30 |last3=Bird |year=1998 |pmid=9647637 |pmc=310741|doi=10.1101/gr.8.6.621}}</ref> Other arrangements such as that used by the International Chicken Genome Sequencing Consortium include five pairs of macrochromosomes, five pairs of intermediate chromosomes, and twenty-eight pairs of microchromosomes.<ref name=turkey/><ref name=genome/> Microchromosomes represent approximately one third of the total genome size, and have been found to have a much higher gene density than macrochromosomes. Because of this, it is estimated that the majority of genes are located on microchromosomes,<ref name=evolution/> though due to the difficulty in physically identifying microchromosomes and the lack of [[Microsatellite (genetics)|microsatellite markers]], it has been difficult to place genes on specific microchromosomes.<ref name=genome/>


[[Replication timing]] and recombination rates have been found to differ between microchromosomes and macrochromosomes in chickens. Microchromosomes replicate earlier in the [[S phase]] of [[interphase]] than macrochromosomes.<ref name=mcqueen/> Recombination rates have also been found to be higher on microchromosomes.<ref name=genevar>{{cite journal |last1=Ka-Shu Wong |first1=Gane |last2=Liu |first2=Bin |last3=Wang |first3=Jun |last4=Zhang |first4=Yong |last5=Yang |first5=Xu |last6=Zhang |first6=Zengjin |last7=Meng |first7=Qingshun |last8=Zhou |first8=Jun |last9=Li |first9=Dawei |last10=Zhang |first10=Jingjing |last11=Ni |first11=Peixiang |last12=Li |first12=Songgang |last13=Ran |first13=Longhua |last14=Li |first14=Heng |last15=Zhang |first15=Jianguo |last16=Li |first16=Ruiqiang |last17=Li |first17=Shengting |last18=Zheng |first18=Hongkun |last19=Lin |first19=Wei |last20=Li |first20=Guangyuan |last21=Wang |first21=Xiaoling |last22=Zhao |first22=Wenming |last23=Li |first23=Jun |last24=Ye |first24=Chen |last25=Dai |first25=Mingtao |last26=Ruan |first26=Jue |last27=Zhou |first27=Yan |last28=Li |first28=Yuanzhe |last29=He |first29=Ximiao |last30=Zhang |first30=Yunze |title=A genetic variation map for chicken with 2.8 million single-nucleotide polymorphisms |journal=Nature |volume=432 |issue=7018 |pages=717–22 |year=2004 |pmid=15592405 |pmc=2263125 |doi=10.1038/nature03156|bibcode=2004Natur.432..717B |display-authors=8 }}</ref> Possibly due to the high recombination rates, chicken chromosome 16 (a microchromosome) has been found to contain the most genetic diversity of any chromosome in certain [[List of chicken breeds|chicken breeds]].<ref name=genevar/> This is likely due to the presence on this chromosome of the major histocompatibility complex (MHC).
[[Replication timing]] and recombination rates have been found to differ between micro- and macrochromosomes in chickens. Microchromosomes replicate earlier in the [[S phase]] of [[interphase]] than macrochromosomes.<ref name=mcqueen/> Recombination rates have also been found to be higher on microchromosomes.<ref name=genevar>{{cite journal |last1=Ka-Shu Wong |first1=Gane |last2=Liu |first2=Bin |last3=Wang |first3=Jun |last4=Zhang |first4=Yong |last5=Yang |first5=Xu |last6=Zhang |first6=Zengjin |last7=Meng |first7=Qingshun |last8=Zhou |first8=Jun |last9=Li |first9=Dawei |last10=Zhang |first10=Jingjing |last11=Ni |first11=Peixiang |last12=Li |first12=Songgang |last13=Ran |first13=Longhua |last14=Li |first14=Heng |last15=Zhang |first15=Jianguo |last16=Li |first16=Ruiqiang |last17=Li |first17=Shengting |last18=Zheng |first18=Hongkun |last19=Lin |first19=Wei |last20=Li |first20=Guangyuan |last21=Wang |first21=Xiaoling |last22=Zhao |first22=Wenming |last23=Li |first23=Jun |last24=Ye |first24=Chen |last25=Dai |first25=Mingtao |last26=Ruan |first26=Jue |last27=Zhou |first27=Yan |last28=Li |first28=Yuanzhe |last29=He |first29=Ximiao |last30=Zhang |first30=Yunze |title=A genetic variation map for chicken with 2.8 million single-nucleotide polymorphisms |journal=Nature |volume=432 |issue=7018 |pages=717–22 |year=2004 |pmid=15592405 |pmc=2263125 |doi=10.1038/nature03156 |bibcode=2004Natur.432..717B |display-authors=8}}</ref> Possibly due to the high recombination rates, chicken chromosome 16 (a microchromosome) has been found to contain the most genetic diversity of any chromosome in certain [[List of chicken breeds|chicken breeds]].<ref name=genevar/> This is likely due to the presence on this chromosome of the major histocompatibility complex (MHC).


For the many small linkage groups in the chicken genome which have not been placed on chromosomes, the assumption has been made that they are located on the microchromosomes. Groups of these correspond almost exactly with large sections of certain human chromosomes. For example, linkage groups E29C09W09, E21E31C25W12, E48C28W13W27, E41W17, E54 and E49C20W21 correspond with [[Chromosome 7 (human)|chromosome 7]].<ref name=genome>{{cite journal |first1=Martien A. M. |last1=Groenen |first2=Hans H. |last2=Cheng |first3=Nat |last3=Bumstead |first4=Bernard F. |last4=Benke |first5=W. Elwood |last5=Briles |first6=Terry |last6=Burke |first7=Dave W. |last7=Burt |first8=Lyman B. |last8=Crittenden |first9=Jerry |last10=Hillel |first10=J |last11=Lamont |first11=S |last12=De Leon |first12=A. P. |last13=Soller |first13=M |last14=Takahashi |first14=H |last15=Vignal |first15=A |last9=Dodgson |title=A consensus linkage map of the chicken genome |journal=Genome Research |volume=10 |issue=1 |pages=137–47 |year=2000 |pmid=10645958 |pmc=310508|display-authors=8 | doi = 10.1101/gr.10.1.137|doi-broken-date=31 October 2021 }}</ref>
For the many small linkage groups in the chicken genome which have not been placed on chromosomes, the assumption has been made that they are located on the microchromosomes. Groups of these correspond almost exactly with large sections of certain human chromosomes. For example, linkage groups E29C09W09, E21E31C25W12, E48C28W13W27, E41W17, E54 and E49C20W21 correspond with [[Chromosome 7 (human)|chromosome 7]].<ref name=genome>{{cite journal |first1=Martien A. M. |last1=Groenen |first2=Hans H. |last2=Cheng |first3=Nat |last3=Bumstead |first4=Bernard F. |last4=Benke |first5=W. Elwood |last5=Briles |first6=Terry |last6=Burke |first7=Dave W. |last7=Burt |first8=Lyman B. |last8=Crittenden |first9=Jerry |last10=Hillel |first10=J |last11=Lamont |first11=S |last12=De Leon |first12=A. P. |last13=Soller |first13=M |last14=Takahashi |first14=H |last15=Vignal |first15=A |last9=Dodgson |title=A consensus linkage map of the chicken genome |journal=Genome Research |volume=10 |issue=1 |pages=137–47 |year=2000 |pmid=10645958 |pmc=310508 |display-authors=8 |doi=10.1101/gr.10.1.137 |doi-broken-date=31 January 2024}}</ref>


===Turkey===
===Turkey===
The [[Wild turkey|turkey]] has a [[Ploidy#Diploid|diploid]] number of 80 (2''n'' = 80) chromosomes. The karyotype contains an additional chromosomal pair relative to the chicken due to the presence of at least two fission/fusion differences (GGA2 = MGA3 and MGA6 and GGA4 = MGA4 and MGA9). Given these differences involving the macrochromosomes, an additional fission/fusion must also exist between the species involving the microchromosomes if the diploid numbers are valid. Other rearrangements have been identified through comparative genetic maps,<ref>{{cite journal |last1=Reed |first1=K.M. |last2=Chaves |first2=L.D. |last3=Mendoza |first3=K.M. |title=An integrated and comparative genetic map of the turkey genome |journal=Cytogenetic and Genome Research |volume=119 |issue=1–2 |pages=113–26 |year=2007 |pmid=18160790 |doi=10.1159/000109627|s2cid=42494634 }}</ref> physical maps and whole genome sequencing.<ref>{{cite journal |last1=Roberts |first1=Richard J. |last2=Dalloul |first2=Rami A. |last3=Long |first3=Julie A. |last4=Zimin |first4=Aleksey V. |last5=Aslam |first5=Luqman |last6=Beal |first6=Kathryn |last7=Ann Blomberg |first7=Le |last8=Bouffard |first8=Pascal |last9=Burt |first9=David W. |last10=Crooijmans |first10=Richard P. M. A. |last11=Cooper |first11=Kristal |last12=Coulombe |first12=Roger A. |last13=De |first13=Supriyo |last14=Delany |first14=Mary E. |last15=Dodgson |first15=Jerry B. |last16=Dong |first16=Jennifer J. |last17=Evans |first17=Clive |last18=Frederickson |first18=Karin M. |last19=Flicek |first19=Paul |last20=Florea |first20=Liliana |last21=Folkerts |first21=Otto |last22=Groenen |first22=Martien A. M. |last23=Harkins |first23=Tim T. |last24=Herrero |first24=Javier |last25=Hoffmann |first25=Steve |last26=Megens |first26=Hendrik-Jan |last27=Jiang |first27=Andrew |last28=De Jong |first28=Pieter |last29=Kaiser |first29=Pete |last30=Kim |first30=Heebal |title=Multi-Platform Next-Generation Sequencing of the Domestic Turkey (Meleagris gallopavo): Genome Assembly and Analysis |journal=PLOS Biology |volume=8 |issue=9 |pages=e1000475 |year=2010 |pmid=20838655 |pmc=2935454 |doi=10.1371/journal.pbio.1000475|display-authors=8 }}</ref>
The [[Wild turkey|turkey]] has a [[Ploidy#Diploid|diploid]] number of 80 (2''n'' = 80) chromosomes. The karyotype contains an additional chromosomal pair relative to the chicken due to the presence of at least two fission/fusion differences (GGA2 = MGA3 and MGA6 and GGA4 = MGA4 and MGA9). Given these differences involving the macrochromosomes, an additional fission/fusion must also exist between the species involving the microchromosomes if the diploid numbers are valid. Other rearrangements have been identified through comparative genetic maps,<ref>{{cite journal |last1=Reed |first1=K.M. |last2=Chaves |first2=L.D. |last3=Mendoza |first3=K.M. |title=An integrated and comparative genetic map of the turkey genome |journal=Cytogenetic and Genome Research |volume=119 |issue=1–2 |pages=113–26 |year=2007 |pmid=18160790 |doi=10.1159/000109627 |s2cid=42494634}}</ref> physical maps and whole genome sequencing.<ref>{{cite journal |last1=Roberts |first1=Richard J. |last2=Dalloul |first2=Rami A. |last3=Long |first3=Julie A. |last4=Zimin |first4=Aleksey V. |last5=Aslam |first5=Luqman |last6=Beal |first6=Kathryn |last7=Ann Blomberg |first7=Le |last8=Bouffard |first8=Pascal |last9=Burt |first9=David W. |last10=Crooijmans |first10=Richard P. M. A. |last11=Cooper |first11=Kristal |last12=Coulombe |first12=Roger A. |last13=De |first13=Supriyo |last14=Delany |first14=Mary E. |last15=Dodgson |first15=Jerry B. |last16=Dong |first16=Jennifer J. |last17=Evans |first17=Clive |last18=Frederickson |first18=Karin M. |last19=Flicek |first19=Paul |last20=Florea |first20=Liliana |last21=Folkerts |first21=Otto |last22=Groenen |first22=Martien A. M. |last23=Harkins |first23=Tim T. |last24=Herrero |first24=Javier |last25=Hoffmann |first25=Steve |last26=Megens |first26=Hendrik-Jan |last27=Jiang |first27=Andrew |last28=De Jong |first28=Pieter |last29=Kaiser |first29=Pete |last30=Kim |first30=Heebal |title=Multi-Platform Next-Generation Sequencing of the Domestic Turkey (Meleagris gallopavo): Genome Assembly and Analysis |journal=PLOS Biology |volume=8 |issue=9 |pages=e1000475 |year=2010 |pmid=20838655 |pmc=2935454 |doi=10.1371/journal.pbio.1000475 |display-authors=8 |doi-access=free }}</ref>


== In turtles ==
== In turtles ==
Microchromosomes play a key role in [[ZW sex-determination system|sex determination]] in [[Trionychidae|soft-shelled turtles]].<ref>{{Cite journal|last1=Badenhorst|first1=Daleen|last2=Stanyon|first2=Roscoe|last3=Engstrom|first3=Tag|last4=Valenzuela|first4=Nicole|date=2013-03-20|title=A ZZ/ZW microchromosome system in the spiny softshell turtle, Apalone spinifera, reveals an intriguing sex chromosome conservation in Trionychidae|url=http://dx.doi.org/10.1007/s10577-013-9343-2|journal=Chromosome Research|volume=21|issue=2|pages=137–147|doi=10.1007/s10577-013-9343-2|pmid=23512312|s2cid=14434440|issn=0967-3849}}</ref>
Microchromosomes play a key role in [[ZW sex-determination system|sex determination]] in [[Trionychidae|soft-shelled turtles]].<ref>{{Cite journal |last1=Badenhorst |first1=Daleen |last2=Stanyon |first2=Roscoe |last3=Engstrom |first3=Tag |last4=Valenzuela |first4=Nicole |date=2013-03-20 |title=A ZZ/ZW microchromosome system in the spiny softshell turtle, Apalone spinifera, reveals an intriguing sex chromosome conservation in Trionychidae |url=http://dx.doi.org/10.1007/s10577-013-9343-2 |journal=Chromosome Research |volume=21 |issue=2 |pages=137–147 |doi=10.1007/s10577-013-9343-2 |pmid=23512312 |s2cid=14434440 |issn=0967-3849}}</ref>


==In humans and other animals==
==In humans and other animals==
Microchromosomes are absent from the karyotypes of [[mammal]]s<ref name=Waters21/> and some [[amphibians]].<ref>{{cite journal |last1=Zlotina |first1=A |last2=Dedukh |first2=D |last3=Krasikova |first3=A |title=Amphibian and Avian Karyotype Evolution: Insights from Lampbrush Chromosome Studies. |journal=Genes |date=8 November 2017 |volume=8 |issue=11 |page=311 |doi=10.3390/genes8110311 |pmid=29117127|pmc=5704224 |doi-access=free }}</ref> (The [[monotreme]] [[platypus]] has an intermediate karyotype with smaller chromosomes that are not quite "micro".)<ref name=Waters21/>
Microchromosomes are absent from the karyotypes of [[mammal]]s, [[crocodilian]]s, and [[frog]]s.<ref name=fillon/> {{citation needed|reason=a 1998 source is outdated|date=August 2020}}


In rare cases, microchromosomes have been observed in the karotypes of individual humans. A link has been suggested between microchromosome presence and certain genetic disorders like [[Down syndrome]]<ref>{{cite journal |last1=Ramos |first1=C |last2=Rivera |first2=L |last3=Benitez |first3=J |last4=Tejedor |first4=E |last5=Sanchez-Cascos |first5=A |title=Recurrence of Down's syndrome associated with microchromosome |journal=Human Genetics |volume=49 |issue=1 |pages=7–10 |year=1979 |pmid=157321 | doi = 10.1007/BF00277682|doi-broken-date=31 October 2021 }}</ref> and [[fragile X syndrome]].<ref>{{cite journal |last1=López-Pajares |first1=I. |last2=Delicado |first2=A. |last3=Pascual-Castroviejo |first3=I. |last4=López-Martin |first4=V. |last5=Moreno |first5=F. |last6=Garcia-Marcos |first6=J. A. |title=Fragile X syndrome with extra microchromosome |journal=Clinical Genetics |volume=45 |issue=4 |pages=186–9 |year=1994 |pmid=8062436 |doi=10.1111/j.1399-0004.1994.tb04020.x|s2cid=35421842 }}</ref> The smallest chromosome in humans is normally [[Chromosome 21 (human)|chromosome 21]], which is 47 Mb.
In rare cases, microchromosomes have been observed in the karotypes of individual humans. A link has been suggested between microchromosome presence and certain genetic disorders like [[Down syndrome]]<ref>{{cite journal |last1=Ramos |first1=C |last2=Rivera |first2=L |last3=Benitez |first3=J |last4=Tejedor |first4=E |last5=Sanchez-Cascos |first5=A |title=Recurrence of Down's syndrome associated with microchromosome |journal=Human Genetics |volume=49 |issue=1 |pages=7–10 |year=1979 |pmid=157321 |doi=10.1007/BF00277682|s2cid=6251717 }}</ref> and [[fragile X syndrome]].<ref>{{cite journal |last1=López-Pajares |first1=I. |last2=Delicado |first2=A. |last3=Pascual-Castroviejo |first3=I. |last4=López-Martin |first4=V. |last5=Moreno |first5=F. |last6=Garcia-Marcos |first6=J. A. |title=Fragile X syndrome with extra microchromosome |journal=Clinical Genetics |volume=45 |issue=4 |pages=186–9 |year=1994 |pmid=8062436 |doi=10.1111/j.1399-0004.1994.tb04020.x |s2cid=35421842}}</ref> The smallest chromosome in humans is normally [[Chromosome 21 (human)|chromosome 21]], which is 47 Mb.


==See also==
==See also==
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==References==
==References==
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{{Reflist}}
{{Reflist}}



Revision as of 15:07, 16 May 2024

Image of chicken chromosomes featuring the many microchromosomes (appearing as dots). The arrows indicate a stained gene locus on homologous macrochromosomes.

A microchromosome is a chromosome defined for its relatively small size. They are typical components of the karyotype of birds, some reptiles, fish, amphibians, and monotremes.[1] As many bird genomes have chromosomes of widely different lengths, the name was meant to distinguish them from the comparatively large macrochromosomes.[2] The distinction referred to the measured size of the chromosome while staining for karyotype, and while there is not a strict definition, chromosomes resembling the large chromosomes of mammals were called macrochromosomes (roughly 3 to 6 μm), while the much smaller ones of less than around 0.5 μm were called microchromosomes.[3] In terms of base pairs, by convention, those of less than 20Mb were called microchromosomes, those between 20 and 40 Mb are classified as intermediate chromosomes, and those larger than 40Mb are macrochromosomes.[4] By this definition, all normal chromosomes in organisms with relatively small genomes (less than 100-200Mb) would be considered microchromosomes.

Function

Microchromosomes are characteristically very small and often cytogenetically indistinguishable in a karyotype, which makes ordering and identifying chromosomes into a coherent karyotype particularly difficult. While originally thought to be insignificant fragments of chromosomes, in species where they have been studied they have been found to be rich in genes and high in GC content. In chickens, microchromosomes have been estimated to contain between 50 and 75% of all genes.[5][6] During metaphase, they appear merely as 0.5-1.5 μm long specks. Their small size and poor condensation into heterochromatin means they generally lack the diagnostic banding patterns and distinct centromere locations used for chromosome identification.[7]

Occurrence

Microchromosomes are found in many vertebrates, but not in most mammals.[1] Important comparisons were made using the genomic organization of the Florida lancelet – part of a sister group to all vertebrates – suggests that the ancestral amniote (and vertebrates in general) genome consisted entirely of microchromosomes. Comparison between lancelet and modern vertebrate chromosomes shows that the macrochromosomes were the result of fusion between ancestral microchromosomes. In addition, retention of microchromosomes is shown to be the norm; the complete loss of them in mammals is the outlier instead.[3]

Relationship among mentioned organisms

Lancelet

Vertebrates

Garfish

Lungfish

Tetrapods

Amphibians

Amniotes

Mammals

Reptiles
Lepidosaurs

Squamata (snakes, lizards)

A[...]formes

Turtles

Archosaurs

Crocodilians

Birds

In birds

Chickens have a diploid number of 78 (2n = 78) chromosomes, and as is usual in birds, the majority are microchromosomes. Classification of chicken chromosomes varies by author. Some classify them as 6 pairs of macrochromosomes, one pair of sex chromosomes, with the remaining 32 pairs being intermediate or microchromosomes.[5] Other arrangements such as that used by the International Chicken Genome Sequencing Consortium include five pairs of macrochromosomes, five pairs of intermediate chromosomes, and twenty-eight pairs of microchromosomes.[4][8] Microchromosomes represent approximately one third of the total genome size, and have been found to have a much higher gene density than macrochromosomes. Because of this, it is estimated that the majority of genes are located on microchromosomes,[6] though due to the difficulty in physically identifying microchromosomes and the lack of microsatellite markers, it has been difficult to place genes on specific microchromosomes.[8]

Birds (except Falconidae) usually have karyotypes of approximately 80 chromosomes (2n = 80), with only a few being distinguishable macrochromosomes and an average of 60 being microchromosomes.[7] They are more abundant in birds than any other group of animals. Chickens (Gallus gallus) are an important model organism for studying microchromosomes.[7] Examination of microchromosomes in birds has led to the hypotheses that they may have originated as conserved fragments of ancestral macrochromosomes, and conversely that macrochromosomes could have arisen as aggregates of microchromosomes.[7] Comparative genomic analysis shows that microchromosomes contain genetic information which has been conserved across multiple classes of chromosomes. This indicates that at least ten chicken microchromosomes arose from fission of larger chromosomes and that the typical bird karyotype arose 100–250 mya.[6]

Replication timing and recombination rates have been found to differ between micro- and macrochromosomes in chickens. Microchromosomes replicate earlier in the S phase of interphase than macrochromosomes.[5] Recombination rates have also been found to be higher on microchromosomes.[9] Possibly due to the high recombination rates, chicken chromosome 16 (a microchromosome) has been found to contain the most genetic diversity of any chromosome in certain chicken breeds.[9] This is likely due to the presence on this chromosome of the major histocompatibility complex (MHC).

For the many small linkage groups in the chicken genome which have not been placed on chromosomes, the assumption has been made that they are located on the microchromosomes. Groups of these correspond almost exactly with large sections of certain human chromosomes. For example, linkage groups E29C09W09, E21E31C25W12, E48C28W13W27, E41W17, E54 and E49C20W21 correspond with chromosome 7.[8]

Turkey

The turkey has a diploid number of 80 (2n = 80) chromosomes. The karyotype contains an additional chromosomal pair relative to the chicken due to the presence of at least two fission/fusion differences (GGA2 = MGA3 and MGA6 and GGA4 = MGA4 and MGA9). Given these differences involving the macrochromosomes, an additional fission/fusion must also exist between the species involving the microchromosomes if the diploid numbers are valid. Other rearrangements have been identified through comparative genetic maps,[10] physical maps and whole genome sequencing.[11]

In turtles

Microchromosomes play a key role in sex determination in soft-shelled turtles.[12]

In humans and other animals

Microchromosomes are absent from the karyotypes of mammals[3] and some amphibians.[13] (The monotreme platypus has an intermediate karyotype with smaller chromosomes that are not quite "micro".)[3]

In rare cases, microchromosomes have been observed in the karotypes of individual humans. A link has been suggested between microchromosome presence and certain genetic disorders like Down syndrome[14] and fragile X syndrome.[15] The smallest chromosome in humans is normally chromosome 21, which is 47 Mb.

See also

References

  1. ^ a b Ohno, Susumu; Christian, L.C.; Stenius, Christina (September 1962). "Nucleolus-organizing microchromosomes of Gallus domesticus". Experimental Cell Research. 27 (3): 612–614. doi:10.1016/0014-4827(62)90033-2. PMID 13939683.
  2. ^ Hillier, LaDeana W.; International Chicken Genome Sequencing Consortium (December 2004). "Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution". Nature. 432 (7018): 695–716. Bibcode:2004Natur.432..695C. doi:10.1038/nature03154. PMID 15592404.
  3. ^ a b c d Waters, Paul D.; Patel, Hardip R.; Ruiz-Herrera, Aurora; Álvarez-González, Lucía; Lister, Nicholas C.; Simakov, Oleg; Ezaz, Tariq; Kaur, Parwinder; Frere, Celine; Grützner, Frank; Georges, Arthur; Graves, Jennifer A. Marshall (9 November 2021). "Microchromosomes are building blocks of bird, reptile, and mammal chromosomes". Proceedings of the National Academy of Sciences. 118 (45): e2112494118. Bibcode:2021PNAS..11812494W. doi:10.1073/pnas.2112494118. PMC 8609325. PMID 34725164.
  4. ^ a b Axelsson, Erik; Webster, Matthew T.; Smith, Nick G. C.; Burt, David W.; Ellegren, Hans (2005). "Comparison of the chicken and turkey genomes reveals a higher rate of nucleotide divergence on microchromosomes than macrochromosomes". Genome Research. 15 (1): 120–5. doi:10.1101/gr.3021305. PMC 540272. PMID 15590944.
  5. ^ a b c McQueen, Heather A.; Siriaco, Giorgia; Bird, Adrian P. (1998). "Chicken microchromosomes are hyperacetylated, early replicating, and gene rich". Genome Research. 8 (6): 621–30. doi:10.1101/gr.8.6.621. PMC 310741. PMID 9647637.
  6. ^ a b c Burt, D.W. (2002). "Origin and evolution of avian microchromosomes". Cytogenetic and Genome Research. 96 (1–4): 97–112. doi:10.1159/000063018. PMID 12438785. S2CID 26017998.
  7. ^ a b c d Fillon, Valérie (1998). "The chicken as a model to study microchromosomes in birds: a review". Genetics Selection Evolution. 30 (3): 209–19. doi:10.1186/1297-9686-30-3-209. PMC 2707402.
  8. ^ a b c Groenen, Martien A. M.; Cheng, Hans H.; Bumstead, Nat; Benke, Bernard F.; Briles, W. Elwood; Burke, Terry; Burt, Dave W.; Crittenden, Lyman B.; et al. (2000). "A consensus linkage map of the chicken genome". Genome Research. 10 (1): 137–47. doi:10.1101/gr.10.1.137 (inactive 31 January 2024). PMC 310508. PMID 10645958.{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  9. ^ a b Ka-Shu Wong, Gane; Liu, Bin; Wang, Jun; Zhang, Yong; Yang, Xu; Zhang, Zengjin; Meng, Qingshun; Zhou, Jun; et al. (2004). "A genetic variation map for chicken with 2.8 million single-nucleotide polymorphisms". Nature. 432 (7018): 717–22. Bibcode:2004Natur.432..717B. doi:10.1038/nature03156. PMC 2263125. PMID 15592405.
  10. ^ Reed, K.M.; Chaves, L.D.; Mendoza, K.M. (2007). "An integrated and comparative genetic map of the turkey genome". Cytogenetic and Genome Research. 119 (1–2): 113–26. doi:10.1159/000109627. PMID 18160790. S2CID 42494634.
  11. ^ Roberts, Richard J.; Dalloul, Rami A.; Long, Julie A.; Zimin, Aleksey V.; Aslam, Luqman; Beal, Kathryn; Ann Blomberg, Le; Bouffard, Pascal; et al. (2010). "Multi-Platform Next-Generation Sequencing of the Domestic Turkey (Meleagris gallopavo): Genome Assembly and Analysis". PLOS Biology. 8 (9): e1000475. doi:10.1371/journal.pbio.1000475. PMC 2935454. PMID 20838655.
  12. ^ Badenhorst, Daleen; Stanyon, Roscoe; Engstrom, Tag; Valenzuela, Nicole (2013-03-20). "A ZZ/ZW microchromosome system in the spiny softshell turtle, Apalone spinifera, reveals an intriguing sex chromosome conservation in Trionychidae". Chromosome Research. 21 (2): 137–147. doi:10.1007/s10577-013-9343-2. ISSN 0967-3849. PMID 23512312. S2CID 14434440.
  13. ^ Zlotina, A; Dedukh, D; Krasikova, A (8 November 2017). "Amphibian and Avian Karyotype Evolution: Insights from Lampbrush Chromosome Studies". Genes. 8 (11): 311. doi:10.3390/genes8110311. PMC 5704224. PMID 29117127.
  14. ^ Ramos, C; Rivera, L; Benitez, J; Tejedor, E; Sanchez-Cascos, A (1979). "Recurrence of Down's syndrome associated with microchromosome". Human Genetics. 49 (1): 7–10. doi:10.1007/BF00277682. PMID 157321. S2CID 6251717.
  15. ^ López-Pajares, I.; Delicado, A.; Pascual-Castroviejo, I.; López-Martin, V.; Moreno, F.; Garcia-Marcos, J. A. (1994). "Fragile X syndrome with extra microchromosome". Clinical Genetics. 45 (4): 186–9. doi:10.1111/j.1399-0004.1994.tb04020.x. PMID 8062436. S2CID 35421842.