Cytoplasmic male sterility: Difference between revisions

Cytoplasmic male sterility is total or partial male sterility in plants as the result of specific nuclear and mitochondrial interactions.^[1] Male sterility is the failure of plants to produce functional anthers, pollen, or male gametes

Background

The first documentation of male sterility was by Joseph Gottlieb Kölreuter, who observed anther abortion within species and specific hybrids. Cytoplasmic male sterility has now been identified in over 150 plant species.^[2] It is more prevalent than female sterility, either because the male sporophyte and gametophyte are less protected from the environment than the ovule and embryo sac, or because it results from natural selection on mitochondrial genes which are maternally inherited and are thus not concerned with pollen production. Male sterility is easy to detect because a large number of pollen grains are produced and are easily studied. Male sterility is assayed through staining techniques (carmine, lactophenol or iodine), while detection of female sterility is by the absence of seeds. Male-sterile plants may be propagated, since they can still set seed, while female-sterile plants cannot. Male sterility can arise spontaneously via mutations in nuclear and/or cytoplasmic genes.

Male sterility can be either cytoplasmic or cytoplasmic–genetic. Cytoplasmic male sterility (CMS) is caused by the extranuclear genome (mitochondria or chloroplast) and shows maternal inheritance. Manifestation of male sterility in CMS may be controlled either entirely by cytoplasmic factors or by interaction between cytoplasmic and nuclear factors.

Cytoplasmic male sterility

Cytoplasmic male sterility, as the name indicates, is under extranuclear genetic control (under control of the mitochondrial or plastid genomes). It shows non-Mendelian inheritance, with male sterility inherited maternally. In general, there are two types of cytoplasm: N (normal) and aberrant S (sterile) cytoplasms. These types exhibit reciprocal differences.

Cytoplasmic-genetic male sterility

While CMS is controlled by an extranuclear genome, nuclear genes may have the capability to restore fertility. When nuclear restoration of fertility genes (“Rf”) is available for a CMS system in any crop, it is cytoplasmic–genetic male sterility; the sterility is manifested by the influence of both nuclear (with Mendelian inheritance) and cytoplasmic (maternally inherited) genes. There are also restorers of fertility (Rf) genes that are distinct from genetic male sterility genes. The Rf genes have no expression of their own unless the sterile cytoplasm is present. Rf genes are required to restore fertility in S cytoplasm that causes sterility. Thus plants with N cytoplasm are fertile and S cytoplasm with genotype Rf- leads to fertiles while S cytoplasm with rfrf produces only male steriles. Another feature of these systems is that Rf mutations (i.e., mutations to rf or no fertility restoration) are frequent, so that N cytoplasm with Rfrf is best for stable fertility.

Cytoplasmic–genetic male sterility systems are widely exploited in crop plants for hybrid breeding due to the convenience of controlling sterility expression by manipulating the gene–cytoplasm combinations in any selected genotype. Incorporation of these systems for male sterility evades the need for emasculation in cross-pollinated species, thus encouraging cross breeding producing only hybrid seeds under natural conditions.

Cytoplasmic male sterility in hybrid breeding

Hybrid production requires a female plant in which no viable male gametes are borne. Emasculation is done to prevent a plant from producing pollen so that it serves only as a female parent. Another simple way to establish a female line for hybrid seed production is to identify or create a line that is unable to produce viable pollen. Since this male-sterile line cannot self-pollinate, seed formation is dependent upon pollen from the male line. Cytoplasmic male sterility is used in hybrid seed production. In this case, the sterility is transmitted only through the female and all progeny will be sterile. This is not a problem for crops such as onions or carrots where the commodity harvested from the F1 generation is produced during vegetative growth. These CMS lines must be maintained by repeated crossing to a sister line (known as the maintainer line) that is genetically identical except that it possesses normal cytoplasm and is therefore male-fertile. In cytoplasmic–genetic male sterility restoration of fertility is done using restorer lines carrying nuclear genes. The male-sterile line is maintained by crossing with a maintainer line carrying the same nuclear genome as the MS line but with normal fertile cytoplasm.

Cytoplasmic male sterility in hybrid maize breeding

Cytoplasmic male sterility is an important part of hybrid maize production. The first commercial cytoplasmic male sterile, discovered in Texas, is known as CMS-T. The use of CMS-T, starting in the 1950s, eliminated the need for detasseling. In the early 1970s plants containing CMS-T genetics were susceptible to southern corn leaf blight and suffered from widespread loss of yield. Since then CMS types C and S are used instead.^[3] Unfortunately these types are prone to environmentally induced fertility restoration and must be carefully monitored in the field. Environmentally induced, in contrast to genetic, restoration occurs when certain environmental stimuli signal the plant to bypass sterility restrictions and produce pollen anyway.

Genome sequencing of mitochondrial genomes of crop plants has facilitated the identification of promising candidates for CMS-related mitochondrial rearrangements.^[4] The systematic sequencing of new plant species in recent years has also uncovered the existence of several novel RF genes and their encoded proteins. A unified nomenclature for the RF defines protein families across all plant species and facilitates comparative functional genomics. This nomenclature accommodates functional RF genes and pseudogenes, and offers the flexibility needed to incorporate additional RFs as they become available in future.^[5]

References

1. Gómez-Campo C (1999). Biology of Brassica Coenospecies. Elsevier. pp. 186–189. ISBN 978-0-444-50278-0.
2. Schnable P (May 1998). "The molecular basis of cytoplasmic male sterility and fertility restoration". Trends in Plant Science. 3 (5): 175–180. doi:10.1016/S1360-1385(98)01235-7.
3. Weider, Christophe; Stamp, Peter; Christov, Nikolai; Hüsken, Alexandra; Foueillassar, Xavier; Camp, Karl-Heinz; Munsch, Magali (2009). "Stability of Cytoplasmic Male Sterility in Maize under Different Environmental Conditions". Crop Science. 49 (1): 77. doi:10.2135/cropsci2007.12.0694. {{cite journal}}: Unknown parameter |name-list-format= ignored (|name-list-style= suggested) (help)
4. Tuteja R, Saxena RK, Davila J, Shah T, Chen W, Xiao YL, Fan G, Saxena KB, Alverson AJ, Spillane C, Town C, Varshney RK (October 2013). "Cytoplasmic male sterility-associated chimeric open reading frames identified by mitochondrial genome sequencing of four Cajanus genotypes". DNA Research. 20 (5): 485–95. doi:10.1093/dnares/dst025. PMC 3789559. PMID 23792890.
5. Kotchoni SO, Jimenez-Lopez JC, Gachomo EW, Seufferheld MJ (December 2010). "A new and unified nomenclature for male fertility restorer (RF) proteins in higher plants". Plos One. 5 (12): e15906. doi:10.1371/journal.pone.0015906. PMC 3011004. PMID 21203394.

External links

• Biological approaches to preventing gene flow - Co-extra research project on coexistence and traceability of GM and non-GM supply chains