Biochemical and molecular characterization of photosystem I deficiency in the NCS6 mitochondrial mutant of maize

Interorganellar signaling interactions are poorly understood. The maize non-chromosomal stripe (NCS) mutants provide models to study the requirement of mitochondrial function for chloroplast biogenesis and photosynthesis. Previous work suggested that the NCS6 mitochondrial mutation, a cytochrome oxidase subunit 2 (cox2) deletion, is associated with a malfunction of Photosystem I (PSI) in defective chloroplasts of mutant leaf sectors (Gu et al., 1993). We have now quantified the reductions of photosynthetic rates and PSI activity in the NCS6 defective stripes. Major reductions of the plastid-coded PsaC and nucleus-coded PsaD and PsaE PSI subunits and of their corresponding mRNAs are seen in mutant sectors; however, although thepsaA/B mRNA is greatly reduced, levels of PsaA and PsaB (the core proteins of PSI) are only slightly decreased. Levels of the PsaL subunit and its mRNA appear to be unchanged. Tested subunits of other thylakoid membrane complexes – PSII, Cyt b₆/f, and ATP synthase, have minor (or no) reductions within mutant sectors. The results suggest that specific signaling pathways sense the dysfunction of the mitochondrial electron transport chain and respond to down-regulate particular PSI mRNAs, leading to decreased PSI accumulation in the chloroplast. The reductions of both nucleus and plastid encoded components indicate that complex interorganellar signaling pathways may be involved.     

The YELLOW VARIEGATED (VAR2) locus encodes a homologue of FtsH, an ATP-dependent protease in Arabidopsis

Variegated leaves are often caused by a nuclear recessive mutation in higher plants. Characterization of the gene responsible for variegation has shown to provide several pathways involved in plastid differentiation. Here we describe an Arabidopsis variegated mutant isolated by T-DNA tagging. The mutant displayed green and yellow sectors in all green tissues except for cotyledons. Cells in the yellow sector of the mutant contained both normal-appearing and mutant chloroplasts. The isolated mutant was shown to be an allele of the previously reported mutant, yellow variegated (var2). Cloning and molecular characterization of the VAR2 locus revealed that it potentially encodes a chloroplastic homologue of FtsH, an ATP-dependent metalloprotease that belongs to a large protein family involved in various cellular functions. ftsH-like genes appear to comprise a small gene family in Arabidopsis genome, since at least six homologues were found in addition to VAR2. Dispensability of VAR2 was therefore explained by the redundancy of genes coding for FstHs. In the yellow regions of the mutant leaves, accumulation of photosynthetic protein components in the thylakoid membrane appeared to be impaired. Based on the role of FtsH in a protein degradation pathway in plastids, we propose a possibility that VAR2 is required for plastid differentiation by avoiding partial photooxidation of developing chloroplasts.     

Variegation mutants and mechanisms of chloroplast biogenesis

Variegated plants typically have green‐ and white‐sectored leaves. Cells in the green sectors contain normal‐appearing chloroplasts, whereas cells in the white sectors lack pigments and appear to be blocked at various stages of chloroplast biogenesis. Variegations can be caused by mutations in nuclear, chloroplast or mitochondrial genes. In some plants, the green and white sectors have different genotypes, but in others they have the same (mutant) genotype. One advantage of variegations is that they provide a means of studying genes for proteins that are important for chloroplast development, but for which mutant analysis is difficult, either because mutations in a gene of interest are lethal or because they do not show a readily distinguishable phenotype. This paper focuses on Arabidopsis variegations, for which the most information is available at the molecular level. Perhaps the most interesting of these are variegations caused by defective nuclear gene products in which the cells of the mutant have a uniform genotype. Two questions are of paramount interest: (1) What is the gene product and how does it function in chloroplast biogenesis? (2) What is the mechanism of variegation and why do green sectors arise in plants with a uniform (mutant) genotype? Two paradigms of variegation mechanism are described: immutans (im) and variegated2 (var2). Both mechanisms emphasize compensating activities and the notion of plastid autonomy, but redundant gene products are proposed to play a role in var2, but not in im. It is hypothesized that threshold levels of certain activities are necessary for normal chloroplast development.     

Chloroplast Structure and Function Is Altered in the NCS2 Maize Mitochondrial Mutant

The nonchromosomal stripe 2 (NCS2) mutant of maize (Zea mays L.) has a DNA rearrangement in the mitochondrial genome that segregates with the abnormal growth phenotype. Yet, the NCS2 characteristic phenotype includes striped sectors of pale-green tissue on the leaves. This suggests a chloroplast abnormality. To characterize the chloroplasts present in the mutant sectors, we examined the chloroplast structure by electron microscopy, chloroplast function by radiolabeled carbon dioxide fixation and fluorescence induction kinetics, and thylakoid protein composition by polyacrylamide gel electrophoresis. The data from these analyses suggest abnormal or prematurely arrested chloroplast development. Deleterious effects of the NCS2 mutant mitochondria upon the cells of the leaf include structural and functional alterations in the both the bundle sheath and mesophyll chloroplasts.     

A mutation causing variegation and abnormal development in tobacco is associated with an altered mitochondrial DNA

A variegated mutation appeared in the leaves of a tobacco cybrid plant resulting from fusion of protoplasts from tobacco with Petunia . The mutation was inherited maternally. The light green coloration of leaf sectors resulted from a substitution of spongy parenchyma for palisade parenchyma. No defects were detected in the chloroplasts of the plants, which were derived from Petunia . The mitochondria, as judged by the electrophoretic pattern of their DNA after digestion with restriction endonucleases, were very similar to mitochondria of tobacco, although with some unique cybrid-specific fragments. A second round of fusions was performed to confirm that mitochondria, rather than chloroplasts, were associated with the variegated phenotype. In these fusions, the Petunia chloroplasts of the variegated plants were replaced by tobacco chloroplasts. The mitochondria, according to the DNA restriction pattern, retained all or some of the unique cybrid-specific fragments found in the original variegated tobacco cybrid. Since the variegated phenotype remained after the chloroplast exchange, the chloroplast DNA cannot be the site of the mutation which is responsible for the mutant phenotype. This result eliminates the chloroplast and confirms that the mitochondrial genome is associated with the mutant phenotype.     

Characterization of a zebra mutant of rice with increased susceptibility to light stress

The rice zebra mutant TCM248 is a single recessive mutant. This mutant develops transverse-striped leaves with green and white sectors under alternate light/dark growth conditions. Mutants that were grown under a higher light intensity during the light period showed a more intense striped phenotype. The white tissues contained abnormal chloroplasts with few internal membrane structures, while the green tissues in the mutants contained normal chloroplasts. The white tissue contained only trace amounts of Chls and carotenoids, and mRNA accumulation of nuclear genes encoding chloroplast proteins (rbcS, cab) was strongly suppressed compared to that in the wild type plants. A series of growth condition shift experiments demonstrated that the mutant displayed the striped phenotype only if it was exposed to the alternate light/dark growth conditions during a limited stage of early leaf development. These data suggest that the zebra gene is involved in the acquisition of photoprotective capacity of the plants and that this gene functions at an early stage of chloroplast differentiation.     

Differential expression of alternative oxidase genes in maize mitochondrial mutants

We have examined the expression of three alternative oxidase (aox) genes in two types of maize mitochondrial mutants. Nonchromosomal stripe (NCS) mutants carry mitochondrial DNA deletions that affect subunits of respiratory complexes and show constitutively defective growth. Cytoplasmic male-sterile (CMS) mutants have mitochondrial DNA rearrangements, but they are impaired for mitochondrial function only during anther development. In contrast to normal plants, which have very low levels of AOX, NCS mutants exhibit high expression of aox genes in all nonphotosynthetic tissues tested. The expression pattern is specific for each type of mitochondrial lesion: the NADH dehydrogenase-defective NCS2 mutant has high expression of aox2, whereas the cytochrome oxidase-defective NCS6 mutant predominantly expresses aox3. Similarly, aox2 and aox3 can be induced differentially in normal maize seedlings by specific inhibitors of these two respiratory complexes. Translation-defective NCS4 plants show induction of both aox2 and aox3. AOX2 and AOX3 proteins differ in their ability to be regulated by reversible dimerization. CMS mutants show relatively high levels of aox2 mRNAs in young tassels but none in ear shoots. Significant expression of aox1 is detected only in NCS and CMS tassels. The induction pattern of maize aox genes could serve as a selective marker for diverse mitochondrial defects.     

A partially assembled complex I in NAD4-deficient mitochondria of maize

The proton-translocating NADH:ubiquinone oxidoreductase (respiratory complex I) consists of at least 32 subunits in higher plants, nine of which are mitochondrially encoded (NAD 1–7, NAD4L, NAD9). Complex I (CI) has been analyzed from a mitochondrial mutant of maize, NCS2, that carries a deletion for the 3′ end of the nad4 gene. Mitochondria from highly defective, near-homoplasmic mutant plants have only trace amounts of the normal complex I. Instead, a reduced amount of a smaller complex, which also exhibits NADH dehydrogenase activity, is detected on ‘blue-native’ polyacrylamide gels. Subunits of 76 kDa, 40 kDa and 55 kDa, as well as NAD7 and NAD9, have been identified in the subcomplex by their cross-reactivity with heterologous antisera. The corresponding subunits in Neurospora are localized in a ‘peripheral arm’ of CI, which is known to assemble independently of a ‘membrane arm’. The maize NCS2 CI subcomplex is loosely bound to the membrane and is missing several subunits that could be membrane components. Thus, the mutant CI subcomplex may consist of a peripheral arm. A reduction in the steady-state levels of NAD7 and NAD9 in NCS2 mitochondria occurs despite normal rates of biosynthesis and there is a concomitant decrease of the nuclear encoded 76 kDa subunit. The reduction in CI-associated NADH dehydrogenase activity in the nad4 -deficient NCS2 mutant mitochondria is not associated with a compensatory increase in the activities or amounts of the putative ‘exogenous’ NAD(P)H dehydrogenases that are found in plant mitochondria.     

一个新的小麦黄化突变体的遗传研究

摘要: 通过对冬小麦“西农1718” 自然黄化突变体多年连续自交、与突变亲本回交以及与其他基因型进行正反交, 研究突变性状的遗传规律。观察统计发现, 突变体中金黄株发育至抽穗－开花期前后死亡, 黄-绿株自交后代表现为1金黄株︰2黄-绿株︰1绿株, 绿株自交后代不再分离; 黄-绿株与突变亲本回交及与其他基因型正反交, 后代均表现为1黄-绿株︰1绿株。遗传分析表明, 该小麦黄化突变体是由一对核基因控制的不完全显性遗传, 其中, 金黄株是纯合体(au/au), 表现为致死, 黄-绿株为杂合体(Au/au), 绿株为纯合体(Au/Au)。     

Mutations in the Arabidopsis gene IMMUTANS cause a variegated phenotype by inactivating a chloroplast terminal oxidase associated with phytoene desaturation.

The immutans (im) mutant of Arabidopsis shows a variegated phenotype comprising albino and green somatic sectors. We have cloned the IM gene by transposon tagging and show that even stable null alleles give rise to a variegated phenotype. The gene product has amino acid similarity to the mitochondrial alternative oxidase. We show that the IM protein is synthesized as a precursor polypeptide that is imported into chloroplasts and inserted into the thylakoid membrane. The albino sectors of im plants contain reduced levels of carotenoids and increased levels of the carotenoid precursor phytoene. The data presented here are consistent with a role for the IM protein as a cofactor for carotenoid desaturation. The suggested terminal oxidase function of IM appears to be essential to prevent photooxidative damage during early steps of chloroplast formation. We propose a model in which IM function is linked to phytoene desaturation and, possibly, to the respiratory activity of the chloroplast.     

The DCL gene of tomato is required for chloroplast development and palisade cell morphogenesis in leaves.

The defective chloroplasts and leaves-mutable (dcl-m) mutation of tomato was identified in a Ds mutagenesis screen. This unstable mutation affects both chloroplast development and palisade cell morphogenesis in leaves. Mutant plants are clonally variegated as a result of somatic excision of Ds and have albino leaves with green sectors. Leaf midribs and stems are light green with sectors of dark green tissue but fruit and petals are wild-type in appearance. Within dark green sectors of dcl-m leaves, palisade cells are normal, whereas in albino areas of dcl-m leaves, palisade cells do not expand to become their characteristic columnar shape. The development of chloroplasts from proplastids in albino areas is apparently blocked at an early stage. DCL was cloned using Ds as a tag and encodes a novel protein of approximately 25 kDa, containing a chloroplast transit peptide and an acidic alpha-helical region. DCL protein was imported into chloroplasts in vitro and processed to a mature form. Because of the ubiquitous expression of DCL and the proplastid-like appearance of dcl-affected plastids, the DCL protein may regulate a basic and universal function of the plastid. The novel dcl-m phenotype suggests that chloroplast development is required for correct palisade cell morphogenesis during leaf development.