禾本科牧草和草坪草雄核发育与单倍体育种研究进展

禾本科牧草与草坪草在农业可持续发展、城市绿化和生态环境保护方面起着至关重要的作用。近年来, 随着生物技术的发展, 国内外在牧草及草坪草雄核发育与单倍体育种研究方面取得了较大进展。该文在归纳总结该领域研究成果的基础上, 对影响禾本科牧草及草坪草雄核发育与单倍体育种的几个主要因素进行了探讨。大量研究结果表明, 供试材料的基因型是影响培养效率的最主要因素。小孢子发育到单核中期至晚期时有利于提高培养效率。培养前花药经过低温和甘露醇等预处理不但可以提高愈伤组织的诱导效率, 还可提高愈伤组织的质量。适宜的激素种类和配比也是影响培养成败的关键因素。同时, 总结了雄核发育再生植株的倍性鉴定方法和加倍技术, 对单倍体育种技术在禾本科牧草及草坪草育种中的应用前景进行了展望。     

Role of Cysteine in Enhancing Androgenesis and Regeneration of Indica Rice (Oryza sativa L.)

The effects of amino acid cysteine to culture systems of microspore-derived callus induction as well as plantlet regeneration were studied. Isolated pollen along with anther walls of basmati cultivars, Pusa basmati 1, Basmati 370 and Basmati 386 were cultured in a medium based on N₆ salts supplemented with or without cysteine following pollen embedment in agarose. The induction and regeneration medium with cysteine gave twice as effective androgenesis and plantlet regeneration in recalcitrant basmati rice cultivars as compared with medium lacking cysteine. Unlike the highly responsive model systems, most of the indica cultivars responded rather poorly in anther culture. So the study may accelerate the introgression of desirable genes into basmati rice using anther culture as a breeding tool. Response of microspores in androgenesis, plant regeneration and albinism was genotype specific. Regeneration of Indica rice varieties remains a limiting factor for researchers undertaking transformation experiments.     

Plastid ultrastructure and DNA related to albinism in androgenetic embryos of various barley (Hordeum vulgare L.) cultivars

In order to understand the occurrence of albinism during androgenesis in barley, a number of plastid parameters were analyzed in microspore-derived embryos and androgenetic plantlets, and the results were compared in albino and non-albino producing cultivars. In the winter cv. Igri, plastids in microspore-derived embryos are characterized by numerous divisions, differentiated thylakoids, low amount of starch and a high DNA content examined by immunoelectron microscopy. After regeneration, the androgenetic plantlets were mostly chlorophyllous. In contrast, in the spring lines tested, the plastids of microspore-derived embryos were rarely dividing amyloplasts in which thylakoids and DNA were scarce and albino plantlets were mainly regenerated. After 2 weeks on the regeneration medium, plastids of Igri chlorophyllous androgenetic plantlets were typical chloroplasts, whereas in spring lines plastids of albino androgenetic plantlets were proplastids with the same characteristics as those in the corresponding microspore-derived embryos. These results strongly suggest that the origin of androgenetic albinism differs in winter and spring cvs.: in the winter cv. Igri plastid alteration may take place during the regeneration step of androgenesis whereas in the tested spring lines plastids are already affected in the microspore-derived embryos meaning that albinism is not initiated during regeneration but originates earlier during the androgenetic process likely as early as the sampling stage.     

Aneuploidy among androgenic progeny of hexaploid triticale (XTriticosecale Wittmack)

Doubled haploids are an established tool in plant breeding and research. Of several methods for their production, androgenesis is technically simple and can efficiently produce substantial numbers of lines. It is well suited to such crops as hexaploid triticale. Owing to meiotic irregularities of triticale hybrids, aneuploidy may affect the efficiency of androgenesis more severely than in meiotically stable crops. This study addresses the issue of aneuploidy among androgenic regenerants of triticale. Plant morphology, seed set and seed quality were better predictors of aneuploidy, as determined cytologically, than flow cytometry. Most aneuploids were hypoploids and these included nullisomics, telosomics, and translocation lines; among 42 chromosome plants were nulli-tetrasomics. Rye chromosomes involved in aneuploidy greatly outnumbered wheat chromosomes; in C₀ rye chromosomes 2R and 5R were most frequently involved. While the frequency of nullisomy 2R was fairly constant in most cross combinations, nullisomy 5R was more frequent in the most recalcitrant combination, and its frequency increased with time spent in culture with up to 70% of green plants recovered late being nullisomic 5R. Given that 5R was not involved in meiotic aberrations with an above-average frequency, it is possible that its absence promotes androgenesis or green plant regeneration. Overall, aneuploidy among tested combinations reduced the average efficiency of double haploid production by 35% and by 69% in one recalcitrant combination, seriously reducing the yield of useful lines.     

The evolution of androgenesis

It is well known that some species produce offspring carrying only female chromosomes by processes such as apomixis and parthenogenesis (generically termed "gynogenesis"). There are also several cases of natural reproduction by androgenesis in which diploid offspring carry nuclear chromosomes from only the male parent. We used population genetics models to investigate the conditions for invasion of rare androgenesis alleles and the consequences of their spread. Our models predict that androgenesis alleles often spread to fixation. If fixation causes the loss of females or female function in the population, population extinction occurs. Therefore, androgenesis alleles represent a new class of selfish genetic elements. Extinction is more likely in dioecious species than in hermaphrodites. Within dioecious species, extinction is more likely when androgenesis occurs via paternal apomixis (vs. fusion or doubling of haploid nuclei) and when females are the heterogametic sex (vs. male heterogamety). The apparent rarity of androgenesis compared to gynogenesis could be because androgenesis is harder to detect and more often leads to population extinction. Also, there could be greater evolutionary constraints on the origin of mutations for androgenesis. We suggest characteristics of groups in which further cases of androgenesis are more likely to be found.     

Development and application of biological technologies in fish genetic breeding

Fish genetic breeding is a process that remolds heritable traits to obtain neotype and improved varieties.For the purpose of genetic improvement,researchers can select for desirable genetic traits,integrate a suite of traits from different donors,or alter the innate genetic traits of a species.These improved varieties have,in many cases,facilitated the development of the aquaculture industry by lowering costs and increasing both quality and yield.In this review,we present the pertinent literatures and summarize the biological bases and application of selection breeding technologies(containing traditional selective breeding,molecular marker-assisted breeding,genome-wide selective breeding and breeding by controlling single-sex groups),integration breeding technologies(containing cross breeding,nuclear transplantation,germline stem cells and germ cells transplantation,artificial gynogenesis,artificial androgenesis and polyploid breeding)and modification breeding technologies(represented by transgenic breeding)in fish genetic breeding.Additionally,we discuss the progress our laboratory has made in the field of chromosomal ploidy breeding of fish,including distant hybridization,gynogenesis,and androgenesis.Finally,we systematically summarize the research status and known problems associated with each technology.     

Improving the efficiency of isolated microspore culture in six-row spring barley: I-optimization of key physical factors

Key message

An improved isolated microspore culture protocol alleviating the recalcitrance typically observed in six-row spring barley was developed by optimizing four key physical factors to increase embryogenesis and reduce albinism.

Abstract

Doubled haploid (DH) plants are completely homozygous individuals that can be generated in just a few months via androgenesis in vitro. DHs are useful tools in genetic research and in plant breeding. Isolated microspore culture (IMC) is the most efficient way to produce DHs, but a strong genotype dependency imposes limitations to its wide application. Six-row, spring barley genotypes are considered as particularly recalcitrant due to a low frequency of embryogenesis and a high rate of albinism. Seeking to develop an efficient IMC protocol for this type of barley, we explored four important factors: (1) the harvest stage of immature spikes, (2) the type of pretreatment applied, (3) the osmotic potential in the induction medium, and (4) the plating density of microspores. This work was first performed using four barley genotypes: two typical six-row spring cultivars (ACCA and Léger), a two-row spring (Gobernadora) and a two-row winter (Igri) cultivar. First, by optimizing the harvest stage for each genotype we obtained a twofold to fourfold increase in the yield of embryogenic microspores. Second, two pretreatments (0.3 M mannitol for 2 days, or a combination of cold and heat over 15 days) both performed significantly better than the commonly used cold pretreatment (28 days at 4 °C). Third, an induction medium-containing mannitol (32 g/l) doubled green plant regeneration. Fourth, a plating density of 10⁶ microspores/ml yielded the highest number of green regenerated plants. Our most important findings were then confirmed using sets of F1s from a six-row, spring-type breeding program.     

Production of androgenetic diploid rainbow trout

Haploid androgenesis was induced in rainbow trout (Salmo gairdneri) when eggs were irradiated with 60Co gamma radiation prior to fertilization. Diploidy was restored to the androgenetic haploid zygotes by suppression of first cleavage division using hydrostatic pressure. Peak survival in the androgenetic diploid lots (32.5-38.9 percent of control) occurred when a pressure shock of 9000 pounds per square inch lasting from one to three minutes was applied to the eggs 345 minutes post-fertilization. Chromosomal analysis confirmed diploidy in the androgenetic individuals and suggested that YY rainbow trout are viable to at least the "eyed stage" of development. Inheritance patterns at two loci confirmed all-paternal inheritance. The relatively high yields of completely homozygous androgenetic rainbow trout and the potential for the use of androgenesis in the production of inbred lines and in genetic studies indicate that androgenesis may become a valuable tool in fish research and breeding.     

Androgenesis,gynogenesis, and parthenogenesis haploids in cucurbit species

Haploids and doubled haploids are critical components of plant breeding. This review is focused on studies on haploids and double haploids inducted in cucurbits through in vitro pollination with irradiated pollen, unfertilized ovule/ovary culture, and anther/microspore culture during the last 30 years, as well as comprehensive analysis of the main factors of each process and comparison between chromosome doubling and ploidy identification methods, with special focus on the application of double haploids in plant breeding and genetics. This review identifies existing problems affecting the efficiency of androgenesis, gynogenesis, and parthenogenesis in cucurbit species. Donor plant genotypes and surrounding environments, developmental stages of explants, culture media, stress factors, and chromosome doubling and ploidy identification are compared at length and discussed as methodologies and protocols for androgenesis, gynogenesis, and parthenogenesis in haploid and double haploid production technologies.     

Pathways to doubled haploidy: chromosome doubling during androgenesis

Production of doubled haploid (DH) plants through androgenesis induction is a promising and convenient alternative to conventional selfing techniques for the generation of pure lines for breeding programs. This process comprises two main steps: induction of androgenesis and duplication of the haploid genome. Such duplication is sometimes indirectly induced by the treatments used to promote androgenic development. But usually, an additional step of direct chromosome doubling must be included in the protocol. Duplication of the haploid genome of androgenic individuals has been thought to occur through three mechanisms: endoreduplication, nuclear fusion and c-mitosis. In this review we will revise and analyze the evidences supporting each of the proposed mechanisms and their relevance during androgenesis induction, embryo/callus development and plant regeneration. Special attention will be devoted to nuclear fusion, whose evidences are accumulating in the last years.     

The effect of genotype on the rate of regeneration of plants in a microspore culture of Triticum aestivum L

The effect of genotype on the productivity of in vitro microspore culture of wheat (Triticum aestivum) was studied. Wheat cultivars and hybrids bred in Kazakhstan and used in the programs on breeding new high-productivity and disease-resistant cultivars and forms of plants were tested. The genotypes that are responsive to androgenesis have been found among the cultivars tested: cultivars Kazakhstanskaya 4, Kazakhstanskaya 5, and hybrids obtained from crosses with the participation of these cultivars (K-6, B-5, and B-10). Such genotypes are recommended to be used as model objects in the studies on androgenesis and plant biotechnology. Based on the use of haploid technology, wheat dihaploid lines were created that are currently tested by breeders.     

Doubled haploid production via anther culture in annual,winter type of caraway (<Emphasis Type="Italic">Carum carvi</Emphasis> L.)

Caraway (Carum carvi L.) is a traditional medicinal and spice cross-pollinated plant species. Although in vitro techniques are recently extensively applied in plant breeding programmes, these are not commonly utilized in caraway. Therefore, based on the protocol for anther culture in carrot (Daucus carota L., a closely related species of caraway in Daucaceae family), in vitro androgenesis in caraway has been studied with the aim to produce completely homozygous inbred lines. Various induction conditions, such as temperature pretreatments, carbon sources and combination of growth regulators in a culture medium as well as the effect of genotype on in vitro androgenesis were examined. Ten breeding lines of winter caraway representing third generation of forced (artificial) self-pollination were used as donor plant material. Cultured anthers produced embryogenic calli, and subsequently two types of regenerated plants were obtained, namely haploids with evident microspore origin, and diploids which may represent somatic (anther wall) regenerants or spontaneous doubled haploids. The ploidy status of regenerated plants was determined by flow cytometry. This is the first report on androgenic doubled haploid production in caraway.     

DNA methylation changes in triticale due to in vitro culture plant regeneration and consecutive reproduction

Doubled haploids of triticale are of interest for plant breeders due to hybrid breeding programs based on cytoplasmic male sterility Tt phenomenon. However, (epi)mutations appearing during in vitro culture regeneration may lead to a phenotypic variation that makes the uniformity of plant materials questionable. Using RP-HPLC genomic DNA methylation of donor doubled haploid plants utilized as a source of tissues for the in vitro regeneration (via androgenesis and somatic embryogenesis) of triticale cv. Bogo and their consecutive generative progeny was evaluated. It was demonstrated that in vitro cultures induced a decrease of the DNA methylation of the regenerants independently of the approach used for plant regeneration. The decrease in DNA methylation of genomic DNA proceeded up to the first/second successive generations followed by the beginning of its reestablishment. Moreover, somatic embryogenesis resulted in a higher level of genomic DNA demethylation in regenerants than androgenesis and the process of methylation seems to be affected by donor plant. It is being speculated that long term changes in genomic DNA methylation may be a source of off-type individuals that may spontaneously arise during plant breeding.     

Oculocutaneous albinism type 1: the last 100 years

Research on human albinism has been central to many of the major discoveries in human genetics. These include the first evidence that Mendel's rules of genetic segregation apply to humans, first published in 1903. Contrary to initial thought that albinism is caused by mutations in a single gene, we now know that the genetics of albinism are complex. The complexity of albinism was hinted at, in early publications, but has only recently been fully appreciated with the advent of molecular techniques. Currently, 12 different genes have been identified, that when mutated, result in a different type of albinism. Oculocutaneous albinism type 1 (OCA1), resulting from mutations of the tyrosinase gene, is genetically and biochemically the best understood type of albinism. Though much of the research in albinism has involved OCA1, there are many unanswered questions about OCA1 and albinism, in general. The next 100 yr should still provide many surprises as did the first 100 yr.     

Oculocutaneous Albinism Type 1: The Last 100 Years

Research on human albinism has been central to many of the major discoveries in human genetics. These include the first evidence that Mendel's rules of genetic segregation apply to humans, first published in 1903. Contrary to initial thought that albinism is caused by mutations in a single gene, we now know that the genetics of albinism are complex. The complexity of albinism was hinted at, in early publications, but has only recently been fully appreciated with the advent of molecular techniques. Currently, 12 different genes have been identified, that when mutated, result in a different type of albinism. Oculocutaneous albinism type 1 (OCA1), resulting from mutations of the tyrosinase gene, is genetically and biochemically the best understood type of albinism. Though much of the research in albinism has involved OCA1, there are many unanswered questions about OCA1 and albinism, in general. The next 100 yr should still provide many surprises as did the first 100 yr.     

Improving the efficiency of isolated microspore culture in six-row spring barley: II-exploring novel growth regulators to maximize embryogenesis and reduce albinism

Key message

Two alternative cytokinins, thidiazuron and meta-topoline, were tested in isolated microspore culture on recalcitrant barley genotypes (six-row, spring), and green plant regeneration was improved substantially.

Abstract

Doubled-haploid (DH) plants are coveted in plant breeding and in genetic studies, since they are rapidly obtained and perfectly homozygous. In barley, DHs are produced mainly via androgenesis, and isolated microspore culture (IMC) constitutes the method offering the greatest potential efficiency. However, IMC can often be challenging in some genotypes because of low yield of microspores, low regeneration and high incidence of albinism. Six-row spring-type barleys, the predominant type grown in Eastern Canada, are considered recalcitrant in this regard. Our general objective was to optimize an IMC protocol for DH production in six-row spring barley. In particular, we explored the use of alternative hormones in the induction medium (thidiazuron and dicamba), and in the regeneration medium (meta-topoline). This optimization was performed on two typical six-row spring (ACCA and Léger), a two-row spring (Gobernadora) and a two-row winter (Igri) barley cultivar. When 6-benzyl-aminopurine (BAP) was replaced by a combination of thidiazuron and dicamba in the induction medium, a 5.1-fold increase (P < 0.01) in the production of green plants resulted. This increase was mainly achieved by a reduction of albinism. Moreover, a 2.9-fold increase (P < 0.01) in embryo differentiation into green plants was obtained using meta-topoline instead of BAP in the regeneration medium. Together, these innovations allowed us to achieve a substantial improvement in the efficiency of IMC in this recalcitrant type of barley. These results were later successfully validated using sets of F1s from a six-row spring barley breeding program.     

Pollen embryogenesis: atavism or totipotency?

Summary The origins of pollen embryogenesis are still in doubt. Totipotency of plant cells has traditionally been put forward as an explanation for this phenomenon but we have found this interpretation to involve some shortcomings. The pollen grain is a highly differentiated structure which should have a very reduced capability of regenerating a whole plant, whereas in some species the induction of androgenesis appears to occur with greater facility than somatic embryogenesis. Furthermore, some microspores seem to have a tendency to morphogenesis and organogenesis; spontaneous androgenesis occurs naturally in various species and many examples also occur of pollen dimorphism. Totipotency would seem to be insufficient to explain androgenesis and we propose that its origin might be found in the phenomenon of atavism. According to studies published on ancestral precursors of pollen, these structures appear to have had high proliferation capacity. The ability to form a multicellular structure from a single haploid cell is shared by the meiocytes of ancestral algae, of the first land plants, and of present-day ferns, which are evolutionarily related to pollen. Atavism is only expressed under certain circumstances, as indeed is androgenesis, normally as a consequence of an environmental stress. Our conclusion is that there is evidence enough to suggest that androgenesis may well be the expression of archaic genes of meiocytes with morphogenic capacity which were naturally expressed in the ancestors of flowering plants.     

Genetic control of albinism in pickerelweed (Pontederia cordata L.)

Pickerelweed (Pontederia cordata L.) is a diploid (2n = 2x = 16) perennial aquaphyte. Preliminary studies revealed that a group of nonalbino pickerelweed plants maintained for breeding and inheritance studies regularly produced albino seedlings. The objective of this experiment was to determine the number of loci, number of alleles, and gene action controlling albinism in pickerelweed. Five nonalbino parental lines were used in this experiment to create S(1) and F(1) populations. F(2) populations were produced through self-pollination of F(1) plants. Evaluation of S(1), F(1), and F(2) generations allowed us to identify a single diallelic locus controlling albinism in these populations of pickerelweed, with albinism completely recessive to normal green leaf production. We propose that this locus be named albino with alleles A and a.