Jump to content

Hybridogenesis in water frogs

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by LilHelpa (talk | contribs) at 14:29, 25 January 2016 (Typos and general fixes, typo(s) fixed: occuring → occurring, In other words → In other words, using AWB). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

The fertile hybrids of European water frogs (genus Pelophylax) reproduce by hybridogenesis (hemiclonally). This means that during gametogenesis, they discard the genome of one of the parental species and produce gametes of the other parental species (containing a genome not recombined with the genome of the first parental species).[1][2][3][4] The first parental genome is restored by fertilization of these gametes with gametes from the first species (sexual host).[5][1][4] In all-hybrid populations of the edible frog Pelophylax kl. esculentus, however, triploid hybrids provide this missing genome.[3][6][2]

Because half of the genome is transmitted to the next generation clonally (not excluded unrecombined intact genome), and only the other half sexually (recombined genome of the sexual host), the hybridogenesis is a hemiclonal mode of reproduction.[7][8][4]

For example, the edible frog Pelophylax kl. esculentus (mostly RL genome), which is a hybridogenetic hybrid of the marsh frog P. ridibundus (RR) and the pool frog P. lessonae (LL), usually excludes the lessonae genome (L) and generates gametes of the P. ridibundus (R). In other words, edible frogs produce gametes of marsh frogs.[2][3][4]

The hybrid populations are propagated, however, not by the above primary hybridisations, but predominantly by backcrossess with one of the parental species they coexist (live in sympatry[9][10]) with (see below in the middle). [11][2][3][12][9][4]

Example crosses between pool frog (Pelophylax lessonae), marsh frog (P. ridibundus) and their hybrid - edible frog (P. kl. esculentus). The first example is the primary hybridization-generating cross.[2] The second one is an example of hybridogenesis and occurs in the most widespread hybridogenetic L–E system,[11][2][3][4][9][12][8] the third example occurs in the R–E system, is less frequent in nature [2][4], but is considered as possible e.g., if an L-E system is invaded by P. ridibundus [8]. P. kl. esculentus × P. kl. esculentus crossings result in inviable P. ridibundus tadpoles and are not shown here.[2][3] Large circles - adult frogs, small circles - gametes, × - lack of gametes containing genome of one of the parental species.

Since the hybridogenetic hybrids require another taxon as sexual host to reproduce, usually one of the parental species, they are called kleptons[13][14][5] (with "kl." in scientific names[15]).

Edible frog Pelophylax kl. esculentus

There are three known hybridogenetic hybrids of the European water frogs:

Parental genome exclusion

Hybridogenesis implies that gametes of hybrids don't contain mixed parental genomes, as normally occurs by independent chromosome segregation and crossover in meiosis (see also second Mendel's law, recombination). Instead, each gamete carries a complete (haploid) genome of only one parent species. Usually one entire genome of the parental species is excluded prior to meiosis during gametogenesis, such that only one (remaining) parental genome is represented among gametes and genes from the other parent are not passed on by the hybridogen.[16][3][2] This discarding occurs gradually during subsequent mitotic divisions, not in one step.[2]

Pelophylax kl. esculentus are a hemiclone here, because they share half of their genome (R haplotype, red arrows). L-E system.
Typical gametogenesis in Pelophylax kl. esculentus (in the L-E system). 1 - exclusion of the P. lessonae genome, 2 - duplication (endoreduplication) of the P. ridibundus genome - restoration of diploidy, 3 - meiosis, L and R - P. lessonae and ridibundus genomes. [16]
Gametes of a hybridogenetic hybrid contain the unrecombined genome of one parental species (C), instead of all possible combinations of both parental (red and green) chromosomes (B).
A - somatic cell.

Hemiclones

Hybridogenesis is a hemiclonal mode of reproduction — half of a hybrid genome is transmitted intact clonally from generation to generation (R genome in the L-E system) — not recombined with a parental species genome (L here), while the other half (L) is transmitted sexually — obtained (replaced) each generation by sexual reproduction with a parental species (sexual host[5][1][4], P. lessonae in the L-E system).[7][8][4]

Hybridogenetic systems overview

There are at least three hybridogenetic species (hybrids) of water frogs in Europe - edible frog Pelophylax kl. esculentus, Graf's hybrid frog Pelophylax kl. grafi and Italian edible frog Pelophylax kl. hispanicus. Their mating patterns are classified into several hybridogenetic systems:[2]

Hybrid Originated from Maintained by
crosses with
Excluded
genome
System
Pelophylax kl. esculentus
RL
P. ridibundus
RR
× P. lessonae
LL
P. lessonae
LL
L L–E
P. ridibundus
RR
R or L 3:1 R–E
P. kl. esculentus
LLR
L from RL
R from LLR
E
P. kl. esculentus
RRL
R or L 3:1 from RL
L from RRL
E
Pelophylax kl. grafi
RP
P. ridibundus ?
RR or
P. kl. esculentus ?
RL
× P. perezi
PP
P. perezi
PP
P P–G
Pelophylax kl. hispanicus
RB
P. ridibundus
RR
× P. bergeri
BB
P. bergeri
BB
B B–H

(capital abbreviations below scientific names are genotypes)

All these hybrids contain genome of marsh frog P. ridibundus (R) and genome of second parental species (L, P or B).[2]

Most of above hybridogenic systems consist of a hybrid coexisting (living in sympatry[9][10]) with one of the parental species required for its reproduction.[2] P. kl. esculentus for example in the most frequent L-E system must mate with P. lessonae to produce new hybrids, in the R-E system with P. ridibundus.[3][4] Because these hybrids depend on other taxa as sexual hosts to reproduce ("parasitize" on them sexually), they are kleptons[13][14][5] ("kl." in scientific names[15]).

Edible frog Pelophylax kl. esculentus

The Pelophylax esculentus complex consists of the hybrid taxon – edible frog P. kl. esculentus (genotype RL) and parental species – marsh frog P. ridibundus (RR) and pool frog P. lessonae (LL). Hybrids are females and males, which is unusual, because hybrids of other hybridogenic species are only females.[2]

The primary hybridisation originating P. kl. esculentus (genotype RL) is:

  • P. lessonae (LL) × P. ridibundus (RR)

It occurs between P. lessonae (LL) males and P. ridibundus (RR) females[11][2][3][9][4], because smaller P. lessonae males prefer larger females.[11][2][3][4] The lineages of hybrids are maintained later through other matings, described below.[2][3][6]

P. lessonae and P. ridibundus have distinct habitat requirements and usually don't live together.[17][18]

P. lessonaeP. kl. esculentus (L–E) system

The P. lessonaeP. kl. esculentus[2] (L–E[2][4][9][12][8], LE[3][6], lessonae–esculentus[3]) system is most widespread hybridogenetic system.[2][4] It is found in Western Europe.[2]

Hybrids P. kl. esculentus (genotype RL) exclude here the P. lessonae genome (L) and make exclusively clonal P. ridibundus gametes (R).[2][4] In other words, edible frogs produce gametes of marsh frogs![4] Their lineages are maintained usually through backcrosses of a female P. kl. esculentus (RL) with a male P. lessonae (LL). The offspring consist of only P. kl. esculentus.[2][3]

P. kl. esculentus hybrids (RL) can mate also with each other, but only 3% of resulting tadpoles (RR) survive to sexual maturity (97% do not). The genomes of interhybrid crosses are female, because of carrying X chromosomes of females from primary hybridisation.[2]

Hybridogenesis - L–E and R–E systems.

P. ridibundusP. kl. esculentus (R–E) system

The P. ridibundusP. kl. esculentus[2] (R–E[2][4], RE[3][6], ridibundus–esculentus[3]) system inhabits Eastern Europe.[2]

It is essentially a reverse form of the L–E system.[2][3]

Hybrids P. kl. esculentus (genotype RL) exclude here the P. ridibundus (R) or P. lessonae (L) genome in a 3:1 ratio and make mainly clonal P. lessonae (L), less P. ridibundus gametes (R).[2] One frog produce either L or R gametes or a mixture of both.[4] Their lineages are maintained through backcrosses of a male[3] P. kl. esculentus (RL) with a female[3] P. ridibundus (RR).[2][3] The offspring consist of P. kl. esculentus males (75%) or P. ridibundus females (25%). This is called hybrid-amphispermy.[2]

All-hybrid populations (E system)

All-hybrid populations[3][2] (E system[2], EE–system[6]) consist exclusively of P. kl. esculentus - diploid RE and triploid LLR or RRL hybrids.[3][2] There are even known tetraploid LLRR hybrids.[3] All-hybrid populations inhabit the entire range of the water frog complex.[3]

RL diploids discard L genome and produce gametes of P. ridibundus (R), or discard R or L genome and produce gametes of P. lessonae (L) or P. ridibundus (R) respectively. In both cases, diploid hybrids generate also not reduced diploid gametes (RL) needed to recreate triploids.[2]

Triploids LLR and RRL are providers of P. lessonae (L)[2] and P. ridibundus gametes (R) respectively in this system lacking both of parental species.[2] So triploid hybrids allow P. kl. esculentus populations to remain without the parental species.[3]

Because triploids discard this genome, which is available in one copy and leave two copies of second genome, they don't perform endoreduplication.[2] Moreover, this not eliminated genome is transmitted to haploid gametes sexually, not clonally (recombined between two L's or between two R's), in contrast to the genome of diploid hybrids.[3][6]

Such modified hybridogenesis[19] (or gametogenetic system[20]) occurring in allotriploid hybrids, where during meiosis chromosomes (genomes) from the doubled set (LL from LLR or RR from RRL here) are used to produce haploid gametes (L or R respectively), whereas the remaining ones may be excluded (R from LLR or L from RRL) is known as meiotic hybridogenesis.[19][20][6]

In one Slovakian population however, triploid males (LLR) and diploid LR females generate clonal LL and clonal R gametes respectively, instead of recombined L and clonal LR.[6]

P. lessonae (LL) and P. ridibundus (RR) offspring do not survive to sexual maturity in the E system.[2][3]

Template:MultiCol

Adults
(P. kl. esculentus)
Gametes
LLR L
LR LR*, R, L**
LRR R


Gametes Offspring
L + L LL P. lessonae
L + LR* LLR P. kl. esculentus
L + R LR
LR* + R LRR
R + R RR P. ridibundus

Template:EndMultiCol

Maintenance of pure (all-hybrid) P. kl. esculentus populations, without P. lessonae and ridibundus.[3]

L, RP. lessonae and P. ridibundus haploid genomes;
LL, RR – do not survive to sexual maturity;
* females only (eggs); ** L gametes are produced by LR, but author doesn't write whether they take part in reproduction or not.

Hybridogenesis - All-hybrid (E) system.

Graf's hybrid frog Pelophylax kl. grafi and the P–G system

Hybridogenesis in Graf's hybrid frog Pelophylax kl. grafi (P–G system).

It is not clear, whether the primary hybridisation which originated Graf's hybrid frog Pelophylax kl. grafi (genotype PR) was:[2]

Unlike P. perezi and Pelophylax kl. grafi, P. ridibundus and P. kl. esculentus do not belong to native fauna of Iberian Peninsula.[2]

Hybrids P. kl. grafi (PR) discard the P. perezi genome (P) and make exclusively clonal P. ridibundus gametes (R). Their lineages are maintained in so called P–G system through backcrosses of P. kl. grafi (PR) with P. perezi (PP).[2]

Italian edible frog Pelophylax kl. hispanicus and the B–H system

Hybridogenesis in Italian edible frog Pelophylax kl. hispanicus (B–H system).

The primary hybridisation which originated Italian edible frog Pelophylax kl. hispanicus (genotype RB) was:[2]

Hybrids Pelophylax kl. hispanicus (RB) discard the P. bergeri genome (B) and make exclusively clonal P. ridibundus gametes (R). Their lineages are maintained in so called B–H system through backcrosses of P. kl. hispanicus (PR) with P. bergeri (BB).[2]

Water frogs and hybridogenesis definition

Matting patterns of hybridogenetic water frogs don't fit precisely known definitions of hybridogenesis:[21][1][7]

  • hybridogenetic hybrids are not only females[21][1][7], but also males[2][3][4]
  • in all-hybrid populations of the edible frog Pelophylax kl. not another species,[21][1] but esculentus triploid hybrids of the same species provide excluded genome,[3][6][2] serving (adopting the role[22]) as the sexual host (sexual host species from definitions[1]),[22][23] what actually is not an exception to the rule.

Mitochondrial DNA

The Pelophylax kl. esculentus complex frogs have either of four phenotypes of mtDNA:[9]

Taxon mtDNA type
A B C D
marsh frog P. ridibundus + +
pool frog P. lessonae + +
edible frog P. kl. esculentus + + + +

Type A is P. ridibundus specific and type B is P. lessonae-like[2] (differs only by 0.3% from type C[9]). Most of P. kl. esculentus have C or D phenotype of the P. lessonae, not P. ridibundus mtDNA.[9][2]

Distribution of these phenotypes don't reflect exactly typical matting patterns. Mitochondria along with the mtDNA are inherited exclusively from the female. Since the primary hybridisations producing P. kl. esculentus occur between P. ridibundus females (large) and P. lessonae males (small) and later are maintained through backcrosses P. kl. esculentus females with P. lessonae males (L–E system[2]), the expected mtDNA phenotype of P. kl. esculentus would be the phenotype of P. ridibundus. This unexpected phenotype distribution might be explained in such a way that most of P. kl. esculentus lineages might go through at least one backcross between P. kl. esculentus male with P. lessonae female.[9][2] And such phenotype pattern suggests, that primary hybridisations are rare.[9]

The introgression of P. lessonae mtDNA in P. ridibundus (type B[9]) might be caused by matting between P. ridibundus and P. kl. esculentus having P. lessonae mtDNA.[2]

Evolutionary origin of hybridogenesis in edible frog

During the ice ages,[clarification needed] the population of the common ancestor of both parental species of the edible frog was split into two. These populations diverged, but remained genetically close enough to be able to create fertile hybrids. However, when edible frogs mate with each other, their offspring are often malformed, so there are no pure populations of edible frogs.

Impact of alien species

Introduction of alien species belonging to water frog complex (Pelophylax esculentus complex), for example, the exotic marsh frog R. ridibunda, may be harmful to native frog populations because of the creation of new hybridisation opportunities and subsequent exclusion of some of genomes from the population. In some cases it was proved.[2][8][24]

See also

References

  1. ^ a b c d e f g Vrijenhoek, Robert C. (1998). "Parthenogenesis and Natural Clones". In Knobil, Ernst; Neill, Jimmy D. (eds.). Encyclopedia of Reproduction. Vol. 3. Academic Press. pp. 695–702. ISBN 978-0-12-227020-8. {{cite book}}: |access-date= requires |url= (help); External link in |chapterurl= (help); Unknown parameter |chapterurl= ignored (|chapter-url= suggested) (help)
  2. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad ae af ag ah ai aj ak al am an ao ap aq ar as at au av aw ax ay az ba bb bc Holsbeek, G.; Jooris, R. (2010). "Potential impact of genome exclusion by alien species in the hybridogenetic water frogs (Pelophylax esculentus complex)" (PDF). Biological Invasions. 12. Springer Netherlands: 1–13. doi:10.1007/s10530-009-9427-2. ISSN 1387-3547. Retrieved 2015-06-21.
  3. ^ a b c d e f g h i j k l m n o p q r s t u v w x y z aa ab ac ad Christiansen, D. G. (2009). "Gamete types, sex determination and stable equilibria of all-hybrid populations of diploid and triploid edible frogs (Pelophylax esculentus) Rana esculenta as deduced from mtDNA analyses" (PDF). BMC Evolutionary Biology. 9 (135). doi:10.1186/1471-2148-9-135. PMC 2709657. PMID 19527499. Retrieved 2015-06-21.{{cite journal}}: CS1 maint: unflagged free DOI (link)
  4. ^ a b c d e f g h i j k l m n o p q r s Ragghianti, M; Bucci, S; Marracci, S; Casola, C; Mancino, G; Hotz, H; Guex, GD; Plötner, J; Uzzell, T. (February 2007). "Gametogenesis of intergroup hybrids of hemiclonal frogs". Genetical Research. 89 (1): 39–45. doi:10.1017/S0016672307008610. Retrieved 2015-06-21.
  5. ^ a b c d Polls Pelaz, Manuel (October 1990). "The Biological Klepton Concept (BKC)". Alytes. 8 (3). ISSCA (International Society for the Study and Conservation of Amphibians): 75–89. Retrieved 2015-06-22.
  6. ^ a b c d e f g h i Pruvost, Nicolas B M; Hoffmann, Alexandra; Reyer, Heinz-Ulrich (Sep 2013). "Gamete production patterns, ploidy, and population genetics reveal evolutionary significant units in hybrid water frogs (Pelophylax esculentus)" (PDF). Ecology and Evolution. 3 (9). John Wiley & Sons Ltd.: 2933–2946. doi:10.1002/ece3.687. PMC 3790541. PMID 24101984. Retrieved 2015-06-21.
  7. ^ a b c d Simon, J.-C.; Delmotte, F.; Rispe, C.; Crease, T. (2003). "Phylogenetic relationships between parthenogens and their sexual relatives: the possible routes to parthenogenesis in animals" (PDF). Biological Journal of the Linnean Society. 79: 151–163. doi:10.1046/j.1095-8312.2003.00175.x. Retrieved 2015-06-21.
  8. ^ a b c d e f Vorburger, Christoph; Reyer, Heinz-Ulrich (2003). "A genetic mechanism of species replacement in European waterfrogs?" (PDF). Conservation Genetics. 4. Kluwer Academic Publishers: 141–155. doi:10.1023/A:1023346824722. ISSN 1566-0621. Retrieved 2015-06-21.
  9. ^ a b c d e f g h i j k l Spolsky, C; Uzzell, T (1986). "Evolutionary history of the hybridogenetic hybrid frog Rana esculenta as deduced from mtDNA analyses". Molecular Biology and Evolution. 3 (1): 44–56. Retrieved 2015-06-21.
  10. ^ a b Christiansen, Ditte G.; Reyer, Heinz-Ulrich (July 2009). "From clonal to sexual hybrids: genetic recombination via triploids in all-hybrid populations of water frogs" (PDF). Evolution. 63 (7): 1754–1768. doi:10.1111/j.1558-5646.2009.00673.x. Retrieved 2015-06-21.
  11. ^ a b c d e Berger, L. (1970). "Some characteristics of the crosses within Rana esculenta complex in postlarval development". Annales Zoologici Warszawa. 27: 374–416.
  12. ^ a b c Abt Tietje, Gaby; Reyer, Heinz-Ulrich (2004). "Larval development and recruitment of juveniles in a natural population of Rana lessonae and Rana esculenta" (PDF). Copeia. 3: 638–646. doi:10.1643/ce-03-273r1. Retrieved 2015-06-21.
  13. ^ a b Dubois, Alain (2009). "Asexual and metasexual vertebrates. Book review" (PDF). Alytes. 27 (2). ISSCA (International Society for the Study and Conservation of Amphibians): 62–66. Retrieved 2015-06-22. John C. Avise, 2008.–Clonality. The genetics, ecology, and evolution of sexual abstinence in vertebrate animals. New York, Oxford University Press: i-xi + 1-237. ISBN 978-0-19-536967-0.
  14. ^ a b Dubois, A.; Günther, R. (1982). "Klepton and synklepton: two new evolutionary systematics categories in zoology". Zoologische Jahrbücher. Abteilung für Systematik, Geographie und Biologie der Tiere. 109. Jena; Stuttgart; New York: Gustav Fischer Verlag: 290–305. ISSN 0044-5193.
  15. ^ a b Dubois, Alain (October 1990). "Nomenclature of parthenogenetic, gynogenetic and hybridogenetic vertebrate taxons: new proposals". Alytes. 8 (3). ISSCA (International Society for the Study and Conservation of Amphibians): 61–74. Retrieved 2015-06-22.
  16. ^ a b Tunner, H. G.; Heppich-Tunner, S. (1991). "Genome exclusion and two strategies of chromosome duplication in oogenesis of a hybrid frog" (PDF). Naturwissenschaften. 78 (1): 32–34. doi:10.1007/BF01134041. Retrieved 2015-06-21.
  17. ^ Berger, L. (1982). "Hibernation of the European water frogs (Rana esculenta complex)". Zoologica Poloniae. 29. Polish Zoological Society: 57–72.
  18. ^ Holenweg Peter, Anna-Katherina (December 2001). "Dispersal rates and distances in adult water frogs, Rana lessonae, R. ridibunda and their hybridogenetic associate R. esculenta". Herpetologica. 57 (4). Herpetologists' League: 449–460. Retrieved 2015-06-21. url2
  19. ^ a b Alves, M. Judite; Coelho, M. Manuela; Collares-Pereira, M. João (1998). "Diversity in the reproductive modes of females of the Rutilus alburnoides complex (Teleostei, Cyprinidae): a way to avoid the genetic constraints of uniparentalism" (PDF). Molecular Biology and Evolution. 15 (10). Society for Molecular Biology and Evolution: 1233–1242. doi:10.1093/oxfordjournals.molbev.a025852. ISSN 0737-4038. Retrieved 2015-06-27.
  20. ^ a b Morishima, K.; Yoshikawa, H.; Arai, K. (2008). "Meiotic hybridogenesis in triploid Misgurnus loach derived from a clonal lineage". Heredity. 100. Nature Publishing Group: 581–586. doi:10.1038/hdy.2008.17. Retrieved 2015-06-24.
  21. ^ a b c Schultz, R. Jack (November–December 1969). "Hybridization, unisexuality, and polyploidy in the teleost Poeciliopsis (Poeciliidae) and other vertebrates". American Naturalist. 103 (934): 605–619. doi:10.1086/282629. JSTOR 2459036.
  22. ^ a b Hoffmann, Alexandra; Reyer, Heinz-Ulrich (4 December 2013). "Genomic effects on advertisement call structure in diploid and triploid hybrid waterfrogs (Anura, Pelophylax esculentus)". BMC Ecology. 13 (47). BioMed Central. doi:10.1186/1472-6785-13-47. PMC 4235041. PMID 24304922. Retrieved 2015-06-25.{{cite journal}}: CS1 maint: unflagged free DOI (link)
  23. ^ Arioli, M.; Jakob, C.; Reyer, H.U. (May 2010). "Genetic diversity in water frog hybrids (Pelophylax esculentus) varies with population structure and geographic location". Molecular Ecology. 19 (9). John Wiley & Sons Ltd: 1814–28. doi:10.1111/j.1365-294X.2010.04603.x. PMID 20374490. Retrieved 2015-06-25.
  24. ^ Quilodrán, Claudio S.; Montoya-Burgos, Juan I.; Currat, Mathias (2015). "Modelling interspecific hybridization with genome exclusion to identify conservation actions: the case of native and invasive Pelophylax waterfrogs" (PDF). Evolutionary Applications. 8. John Wiley & Sons Ltd.: 199–210. doi:10.1111/eva.12245. Retrieved 2015-06-21.