Development and mapping of AFLP markers linked to the sorghum fertility restorer gene rf4.

The restoration of male fertility in the sorghum IS1112 C (A3) male-sterile cytoplasm is through a two-gene gametophytic system involving complementary action of the restoring alleles Rf3 and Rf4. To develop markers suitable for mapping rf4, AFLP technology was applied to bulks of sterile and fertile individuals from a segregating BC(3)F(1) population. Three AFLP markers linked to rf4were identified and subsequently converted to STS/CAPS markers, two of which are co-dominant. Based on a population of 378 BC(1)F(1) individuals, two STS/CAPS markers, LW7 and LW8, mapped to within 5.31 and 3.18 cM, respectively, of rf4, while an STS marker, LW9, was positioned 0.79 cM on the flanking side of rf4. Markers LW8 and LW9 were used to screen sorghum BAC libraries to identify the genomic region encoding rf4. A series of BAC clones shown to represent a genomic region of linkage group E were identified by the rf4-linked markers. A contig of BAC clones flanking the LW9 marker represent seed clones on linkage group E, from which fine mapping of the rf4 locus and chromosome walking can be initiated.

Mitochondrial atp6 transcript editing during microgametogenesis in male-sterile sorghum.

A marked reduction of mitochondrial atp6 transcript-editing capability in sorghum anthers and pollen has been invoked as a factor in the loss of viability of male gametophytes in lines carrying the IS1112C male-sterile cytoplasm. We initiated a systematic examination of transcript editing of sorghum atp6 during microgametogenesis, from microspores through pollen, in two sets of male-fertile and near-isogenic, male-sterile lines. Transcript editing in cDNA populations from fertile lines indicated an average of about 90% editing among 15 sites examined. Parallel samples from sterile lines demonstrated a detectable reduction in editing efficiency, most evident in late pollen samples. However, editing efficiency in these cells averaged 80%, substantially higher than the 20% previously observed. Thus male-sterile lines retain substantial atp6-editing efficiency in an environment where the sterility and fertility restoration traits are stably expressed. Drastically reduced editing of atp6 transcripts in anthers and pollen of male-sterile sorghum is not demonstrable in a field environment; and thus it is not a factor in the loss of microgametophyte viability in this system.

Nuclear genes from Tx CMS maintainer lines are unable to maintain atp6 RNA editing in any anther cell-type in the sorghum bicolor A3 cytoplasm.

RNA editing and cytoplasmic male sterility are two important phenomena associated with higher plant mitochondria. We recently have shown a potential function of RNA editing in CMS development. The frequency of atp6 RNA editing was specifically reduced in anthers of male-sterile Sorghum bicolor, which increased in frequency in partially restored progeny. Here we present data that show that the loss of RNA editing capability also occurs in a second nuclear background that allows the expression of male sterility. Loss of RNA editing thus appears to be associated with unique combinations of male-sterile cytoplasm and non-restoring nuclear backgrounds. In addition, the reduction of RNA editing affects both gametophytic and sporophytic anther cell-types but not other floral tissues. An analysis of F(2) plants exhibiting different levels of fertility indicates a co-segregation of fertility restoration and atp6 RNA editing. The atp6 transcript abundance is similar in seedlings and anthers of male-sterile, partially restored, and male-fertile lines and thus is not associated with loss of atp6 RNA editing in anthers. A model for RNA editing and male sterility based on the data available is presented. Functional correlations with other CMS systems are also discussed.

A unique two-gene gametophytic male sterility system in sorghum involving a possible role of RNA editing in fertility restoration.

The sorghum line IS1112C carries a male sterility-inducing cytoplasm when introduced into nuclear backgrounds that do not include fertility restoration genes. An mtDNA chimeric configuration resulting from recombination/duplication with atp9 resulted in the formation of orf107, a chimeric open reading frame. Transcription of orf107 is driven by three promoters, and abundant whole-length transcripts are detected in male-sterile lines. Fertility restoration is exacted through a unique two-gene gametophytic system requiring complementary action of genes designated Rf3 and Rf4. In male-sterile lines carrying Rf3, or lines restored to fertility, an enhanced nucleolytic transcript processing activity is targeted within orf107, cleaving 75% of whole-length transcripts. Rf3 thus confers or regulates the nucleolytic processing activity. A correlation between the frequency of RNA editing at two sites in orf107 and transcript processing suggests that processing may be dependent on templates edited at these sites. In addition, editing of atp6 transcripts is specifically reduced in anthers/pollen of male-sterile lines. Partially restored F1s and segregating F2s exhibit atp6 editing frequencies consistent with the possibility that Rf4 may confer the restitution of normal editing frequency. Thus RNA editing may be involved in features of fertility restoration in this unusual system.

Cosegregation of single genes associated with fertility restoration and transcript processing of sorghum mitochondrial orf107 and urf209.

Defective nuclear-cytoplasmic interactions leading to aberrant microgametogenesis in sorghum carrying the IS1112C male-sterile cytoplasm occur very late in pollen maturation. Amelioration of this condition, the restoration of pollen viability, involves a novel two-gene gametophytic system, wherein genes designated Rf3 and Rf4 are required for viability of individual gametes. Rf3 is tightly linked to, or represents, a single gene that regulates a transcript processing activity that cleaves transcripts of orf107, a chimeric mitochondrial open reading frame specific to IS1112C. The mitochondrial gene urf209 is also subject to nucleus-specific enhanced transcript processing, 5' to the gene, conferred by a single dominant gene designated Mmt1. Examinations of transcript patterns in F2 and two backcross populations indicated cosegregation of the augmented orf107 and urf209 processing activities in IS1112C. Several sorghum lines that do not restore fertility or confer orf107 transcript processing do exhibit urf209 transcript processing, indicating that the activities are distinguishable. We conclude that the nuclear gene(s) conferring enhanced orf107 and urf209 processing activities are tightly linked in IS1112C. Alternatively, the similarity in apparent regulatory action of the genes may indicate allelic differences wherein the IS1112C Rf3 allele may differ from alleles of maintainer lines by the capability to regulate both orf107 and urf209 processing activities.

Interaction of mitochondrial RNA editing and nucleolytic processing in the restoration of male fertility in sorghum.

Nucleolytic processing of transcripts within mitochondrial orf107, associated with male sterility in sorghum, is regulated by the fertility restoration gene Rf3, conferring 75% cleavage of whole-length transcripts. Two transcript editing sites are 81% and 61% edited in rf3rf3 lines, while these sites are 41% and 10% edited in the remaining whole-length transcripts in an Rf3Rf3 line. RNA editing and processing efficiency in F1 progeny were similar to the Rf3Rf3 parent, and analyses of backcross progeny indicated that all rf3rf3 lines were characterized by high editing efficiency. We postulate that highly edited transcripts within the population are quickly processed in lines carrying Rf3, generating a residual population of poorly edited transcripts. Thus, action of Rf3 may have no direct affect on RNA editing, and may be dependent on a substrate of highly edited transcripts. These data indicate a potentially novel role of RNA editing in gene expression through an influence on the efficiency of transcript processing.

Mutations at specific atp6 codons which cause human mitochondrial diseases also lead to male sterility in a plant.

Defects in the human mitochondrial genetic system result in some diseases. These disorders are the result of rearrangements or point mutations in mitochondrial genes. In higher plants mutations and rearrangements in the mitochondrial DNA are believed to cause cytoplasmic male sterility (CMS), a mitochondrially inherited inability to produce viable pollen. In sorghum, formation of CMS is strongly correlated with anther-specific loss of mitochondrial atp6 RNA editing. Here we show that this loss of atp6 RNA editing mimics point mutations at codons that cause severe disorders in humans. We conclude that (i) loss of RNA editing in sorghum anthers probably causes CMS, (ii) similarities exist in the onset of mitochondrial dysfunction in plant and human tissues, and (iii) the evolutionary appearance of RNA editing provided a mechanism to compensate for otherwise lethal point mutations.

Transcriptional initiation sites in sorghum mitochondrial DNA indicate conserved and variable features.

Transcriptional initiation and processing was examined for three sorghum mitochondrial DNA genes (atp6-1, atp6-2, urf209) and two open reading frames (orf265/130, orf107) to characterize sequences associated with initiation and other transcriptional strategies for this species. The 5' termini of ten transcripts were determined by primer extension, and mtRNA was capped with guanylyl transferase and annealed to anti-sense riboprobes to identify transcriptional initiation regions. Eight transcript termini were suitable substrates for guanylyl transferase, indicating the presence of one (atp6-1, atp6-2, urf209), two (orf265/130), or three (orf107) promoters for the five examples. The majority of the putative promoters were associated with single primer-extension termini, while two examples exhibited two transcript-initiation sites within the promoter. Four examples were characterized by initiated transcripts without subsequent processing, indicating that processing is not obligatory. Each of the putative promoter regions included significant A/T-rich 5' regions, consistent with previous examples, but four exceptions to a consensus core YRTA sequence were identified. The anomalies (AATA, CTTA) suggest plasticity in the primary structure of the core region of higher-plant mitochondrial DNA promoters.

Transcription initiation sites for sorghum mitochondrial atp9 are positioned immediately 3' to trnfM.

Sorghum mitochondrial atp9 is polymorphic among male-sterile cytoplasms, but each cytoplasm is characterized by a major 650 nt transcript, regardless of fertility status. The gene is positioned 323 bp 3' to trnfM. Primer extension revealed multiple atp9 5' transcript termini, distributed from +1 to +28 3' to trnfM; the termini could be labeled with polynucleotide kinase, suggesting that they result from the maturation of trnfM. Guanylyltransferase experiments, however, showed that four of the termini were capable. The juxtaposition of a putative promoter 3' to trnfM results in a unique atp9 transcript population consisting of primary and processed transcripts.

Transcript processing internal to a mitochondrial open reading frame is correlated with fertility restoration in male-sterile sorghum.

A chimeric mitochondrial DNA (mtDNA) configuration of the cytoplasmic male-sterile (cms) sorghum line IS1112C includes a 321 bp open reading frame designated orf107, encoding a predicted polypeptide product of 11.85 kDa. The open reading frame, similar to several other genes associated with cms, consists of amino-terminal sequences derived from an obligate gene. Unlike other examples to date, however, the carboxy-terminal sequences are highly similar to the carboxy terminus of an open reading frame implicated in cms of rice, orf79. The amino-terminal 31 residues of orf107 are 84% similar to atp9, and the carboxy-terminal 49 residues are 57% identical and 80% similar to the carboxy terminus of orf79. Transcripts of orf107 are edited, with four C-to-U changes that alter amino acids. Sorghum lines partially or fully restored to fertility exhibit a high-efficiency internal-orf107 transcript processing activity, precluding abundant whole-length transcripts, while male-sterile lines exhibit only a trace of the activity. Previous data on the abundance of a 12kDa in organello-synthesized polypeptide in male-sterile versus male-fertile lines are correlated with differential orf107 transcript processing activity of these lines. Examinations of backcross and F2 lines suggest a gametophytic mode of restoration, and indicate that enhanced transcript processing activity is necessary, but not sufficient, to restore full fertility. These novel observations indicate that mitochondrial open reading frames associated with cms in different species can include highly similar motifs, and that fertility restoration could involve a mechanism by which synthesis of a cms-associated gene product may be precluded through internal transcript cleavage.

Sorghum mitochondrial orf25 and a related chimeric configuration of a male-sterile cytoplasm.

We describe fundamental characteristics of sorghum mitochondrial orf25, urf209, and a related chimeric configuration, orf265/130, which is restricted to the IS1112C source of cytoplasmic male sterility in sorghum. Transcripts of urf209 are edited at ten nucleotides, resulting in nine amino-acid changes predicted from genomic sequences. The cDNA-predicted polypeptide product is 23.6 kDa, while Western blot analyses identify a product of 20k Da. Transcription of urf209 is characterized by one or two transcripts, dependent on nuclear background, but this difference is not related to male fertility status. The orf265/130 chimeric region includes 288 bp 95% identical to sequences 5' to maize T-cytoplasm T-urf13 and atp6, which includes a common transcription initiation site, and terminates with a recombinational event involving urf209. The urf209 similarity extends 189 bp, followed by sequences duplicated 5' to sorghum atp6-2. Sequences immediately 3' to the atp6-2 similarity include a second in-frame start codon, defining orf130. Structural features 5' to orf130 are shared with motifs found 5' to several translated mitochondrial open reading frames. The orf265/orf130 configuration is uniquely transcribed, and transcripts of orf130 exhibit one silent RNA editing event. Transcription in somatic cells is not altered by male fertility status.

Analysis of silent RNA editing sites in atp6 transcripts of Sorghum bicolor.

We have observed numerous examples of silent or rare non-silent editing sites in the amino-extension and part of the conserved core of mitochondrial atp6 transcripts of Sorghum. In this region of the 1.4-kb atp6-2 mRNA (position 300 to 550) two editing sites, which alter the amino-acid sequence and occur in all cDNAs analysed, were already known, while nine others were found which are silent or occur in a few mRNAs only. Many aspects of RNA editing in the mitochondria of higher plants are still unknown. This includes the influence of genomic background or silent RNA editing. We were interested in the influence of nuclear and mitochondrial backgrounds on RNA editing. Previous preliminary results indicated the possibility of line-specific editing at silent sites. However, a more comprehensive approach gave no consistent evidence for such editing. These results are discussed with respect to their potential impact on the evolution of mitochondrial genes.

Interaction of nuclear and mitochondrial genomes in the alteration of maize mitochondrial orf221 transcripts.

The interaction of nuclear and mitochondrial genomes in the alteration of maize (Zea mays L.) mitochondrial orf221 transcript patterns was examined. Northern analyses involving specific maize nuclear genotypes associated with N, C or S cytoplasms revealed considerable orf221 transcript heterogeneity. F1 progenies were developed from maize inbred-cytoplasm combinations that differed for orf221 transcript patterns. Northern analyses revealed that the presence or level of abundance of certain orf221 transcripts was dependent on nuclear genotype. The maize inbred B37(C) exhibits orf221 transcripts of 3500, 3200, 2800, and 1300 nt whereas the F1 of B37(C) x Ky21(N) does not exhibit a 2800-nt transcript but does give transcripts of 2100 and 1250 nt in addition to 3500-, 3200- and 1300-nt transcripts. Northern analyses also suggested that the size or the presence of certain orf221 transcripts was related to the mitochondrial genome configuration. Maize inbred A619 exhibits a 2300-nt orf221 transcript when associated with N cytoplasm and a 2100-nt orf221 transcript when associated with C and S cytoplasms. As a result of deletion of the gene T-urf13, the A188(T7) mitochondrial mutant exhibits only a 3100-nt orf221 transcript and not the very complex T-urf13/orf221 transcript pattern associated with A188(T). The genetic stock A188(T7) x W64A(N)(2) gives a highly abundant 2100-nt orf221 transcript not detected in A188(T7). Deletion of T-urf13 has enabled the nuclear genotype of W64A(N) to alter orf221 transcript patterns in a manner not detected in T cytoplasm. This observation suggests that alteration of the mitochondrial genomic configuration adjacent to orf221 results in a different response to nuclear gene products from that observed when or2f21 is present in the T mitochondrial genome configuration.

Sorghum mitochondrial atp6: divergent amino extensions to a conserved core polypeptide.

Sorghum mitochondrial atp6 occurs as one copy in the line Tx398 and as two copies in IS1112C. In IS1112C a repeated sequence diverged within the atp6 open reading frames. The two open reading frames (1137 bp, atp6-1; 1002 bp, atp6-2) share an identical conserved region of 756 bp but are flanked 5' by divergent extensions of 246 (atp6-1) or 381 bp (atp6-2). Tx398 carried only atp6-2. The breakpoint of the repeated sequence of the conserved core region corresponds to the amino acid sequence Ser-Pro-Leu-Asp, which is the amino terminus of the proteolytically processed yeast ATP6. The 5' extensions of atp6-1 and atp6-2 were similar to those of rice and maize, respectively. Each open reading is transcribed, however nuclear background influenced transcriptional patterns of atp6-2 in IS1112C.

Conserved sequence blocks 5' to start codons of plant mitochondrial genes.

Three sequence blocks of 10-12 bp are conserved in sequence and order 5' to putative start codons of several higher-plant mitochondrial genes. At least 25 examples were found, primarily associated with coxII, atp6, and orf25, in monocotyledons and dicotyledons. The proximal block can be 9 bp from start codons, and the three blocks generally occur within 100 bp 5' of start codons. In three examples 5' termini of the blocks represent recombination breakpoints, resulting in conservation of the blocks in resultant configurations. The two proximal blocks can form a secondary structure motif. The occurrence of the blocks near start codons, and conserved sequence and order, is consistent with a possible role in translation initiation or regulation.

Genetic analysis of nuclear control of T-urf13/orf221 transcription in T cytoplasm maize.

The mitochondrial gene T-urf13 in T cytoplasm maize is associated with sensitivity to disease toxins and with cytoplasmic male sterility. T-urf13 is co-transcribed with an open reading frame designated orf221. We have detected alterations in the transcription of the T-urf13/orf221 region that are affected by nuclear genotype. There are multiple mRNA transcripts generated from the T-urf13/orf221 region, one of which is a processed 1538-nucleotide (nt) transcript. This 1538-nt transcript is present in Wf9 (T), but was not found in mitochondrial RNAs (mtRNAs) from maize inbreds B14A (T) and 33-16 (T). For B14A (T) a 1500-nt transcript was detected and for 33-16 (T) a 1400-nt transcript was detected. In F1 progeny of the cross of Wf9 (T) x 33-16 (N), only the 1400-nt transcript was present. Genetic analyses revealed this processing event is nuclear controlled with dominant gene action and is independent of nuclear restorer gene Rf1-associated processing events. T-urf13/orf221 transcriptional patterns were shown to vary in both sterile and fertile states. Segregation analysis of a 1100-nt orf221-specific transcript indicated that the genetic basis of nuclear control for the presence of this transcript was relatively simple. Analysis of the A188 (T4) tissue culture mutant, which has reverted to male fertility but displays the same T-urf13/orf221 transcript pattern as A188 (T), indicated no DNA sequence differences between T4-orf221 and T-orf221. Presence of the nuclear gene Rf2 was not necessary for expression of the T4 cytoplasm-associated malefertile phenotype.

Editing of mitochondrial atp9 transcripts from two sorghum lines.

Genomic and cDNA sequences of the ATP synthase complex subunit 9 (atp9) genes from two sorghum lines were determined. Sequences of cDNAs revealed eight C to U transcript editing events resulting in six amino acid changes and a new stop codon which eliminated 12 carboxy-terminal residues, compared to the genomic sequence. Sorghum atp9 has a unique five-residue amino-extension relative to other higher plants. The resulting predicted 79-residue gene product has a molecular weight of 8.179 kDa. The predicted phe-val-phe carboxy-terminus is identical to that from cDNA sequences of wheat, Oenothera, and petunia. Partial editing of transcripts was detected in each sorghum line.

RNA editing of sorghum mitochondrial atp6 transcripts changes 15 amino acids and generates a carboxy-terminus identical to yeast.

Sequencing of sorghum mitochondrial atp6 cDNA clones revealed 19 C-to-U transcript editing events within a 756 bp-conserved core gene; three were silent and 16 resulted in 15 amino acid changes. Only one edit, which was silent, was found in the 381 bp amino-extension to the core gene. Eleven of the 15 changed amino acids were identical with or else represented conservative changes compared to yeast atp6. Editing of a CAA codon to TAA truncates the carboxy-terminus to a position identical to that of yeast. The frequency of editing at sites which change amino acids was very high in contrast to partial editing at silent, third base, sites.

Expression in Saccharomyces cerevisiae of a gene associated with cytoplasmic male sterility from maize: respiratory dysfunction and uncoupling of yeast mitochondria.

We asked whether the mitochondrial T-urf13 gene, associated with the male sterility phenotype of T cytoplasm in maize, can be expressed in Saccharomyces cerevisiae and whether this expression can mimic the effects observed in maize. We introduced the universal code equivalent of the T-urf13 gene into the S. cerevisiae nucleus by transformation and directed its translation product into mitochondria by means of a fusion with the targeting presequence from Neurospora crassa AT-Pase subunit 9. We show that expression of the universal code equivalent of the T-urf13 gene in the yeast nucleus does indeed mimic its effects in maize: respiratory growth of yeast is inhibited, respiration-deficient cytoplasmic mutants accumulate and NADH oxidation of isolated mitochondria is uncoupled. All these effects are observed only if the mitochondrial targeting peptide and methomyl or HmT toxin are present.

Recombination is associated with polymorphism of the mitochondrial genomes of maize and sorghum.

Extensive recombination events characterize higher-plant mitochondrial DNAs. Numerous recombination events resulted in the appearance of an unusual mitochondrial open reading frame, urf13-T, which encodes a 13 kDa polypeptide in the male-sterile T cytoplasm of maize. Maize lines with T cytoplasm are unusually susceptible to two fungal pathogens which produce host-selective toxins. Mutants derived from tissue culture expressing male fertility and toxin-insensitivity are characterized by truncation or deletion of urf13-T. These events result from a frameshift associated with a tandem 5 base pair repeat, placing a premature stop codon in frame, or from a recombination event, apparently limited to tissue culture, resulting in the deletion of urf13-T. Neither class of mutants produces the 13 kDa gene product. Repeated sequences that participate in recombination in sorghum appear to be randomly distributed among male-fertile or male-sterile cytoplasms. Processes involved in the evolution of mitochondrial DNAs in higher plants therefore include the generation and deletion of configurations through recombination.