A male sterility-associated mitochondrial protein in wild beets causes pollen disruption in transgenic plants

In higher plants, male reproductive (pollen) development is known to be disrupted in a class of mitochondrial mutants termed cytoplasmic male sterility (CMS) mutants. Despite the increase in knowledge regarding CMS-encoding genes and their expression, definitive evidence that CMS-associated proteins actually cause pollen disruption is not yet available in most cases. Here we compare the translation products of mitochondria between the normal fertile cytoplasm and the male-sterile I-12CMS(3) cytoplasm derived from wild beets. The results show a unique 12 kDa polypeptide that is present in the I-12CMS(3) mitochondria but is not detectable among the translation products of normal mitochondria. We also found that a mitochondrial open reading frame (named orf129 ) was uniquely transcribed in I-12CMS(3) and is large enough to encode the novel 12 kDa polypeptide. Antibodies against a GST–ORF129 fusion protein were raised to establish that this 12 kDa polypeptide is the product of orf129. ORF129 was shown to accumulate in flower mitochondria as well as in root and leaf mitochondria. As for the CMS-associated protein (PCF protein) in petunia, ORF129 is primarily present in the matrix and is loosely associated with the inner mitochondrial membrane. The orf129 sequence was fused to a mitochondrial targeting pre-sequence, placed under the control of the Arabidopsis apetala3 promoter, and introduced into the tobacco nuclear genome. Transgenic expression of ORF129 resulted in male sterility, which provides clear supporting evidence that ORF129 is responsible for the male-sterile phenotype in sugar beet with wild beet cytoplasm.     

Correlation between the rate of proteolysis of mitochondrial translation products and fluidity of the mitochondrial inner membrane in Saccharomyces cerevisiae yeast. Alteration of the rate of proteolysis under glucose repression.

Our previous results [Kalnov, Novikova, Zubatov & Luzikov (1979) FEBS Lett. 101, 355-358; Biochem. J. 182, 195-202] suggested that in yeast the mitochondrial translation products localized in the mitochondrial inner membrane are rapidly broken down by a proteolytic system inherent in the membrane. In the present work, it is demonstrated that, on glucose repression in undividing cells of Saccharomyces cerevisiae, there is no proteolysis of the mitochondrial translation products. This effect is not likely to be associated with lower activity of the proteolytic system of the mitochondrial inner membrane. Nor is the cessation of proteolysis due to qualitative changes in the composition of mitochondrial translation products. What repression does cause is a considerable alteration in the physical state (i.e. structure of the lipid bilayer) of the mitochondrial inner membrane; this was established by experiments involving lipid-soluble spin probes. The conclusion is reached that the rate of proteolysis of mitochondrial translation products in the mitochondrial inner membrane depends on the physical state of the membrane, which in its turn is controlled by the relative content of unsaturated fatty acid chains in the mitochondrial phospholipids.     

The orientation of transhydrogenase in the inner mitochondrial membrane of rat liver

The orientation of the transmembranous enzyme, pyridine dinucleotide transhydrogenase, in the inner mitochondrial membrane of rat liver has been determined by evaluating effects of proteases on the integrity of the enzyme in mitoplasts and submitochondrial particles. Following treatment of these membranes with the nonspecific protease, proteinase K, antigenic proteolytic products were detected by immunoblot analysis using polyclonal antibody prepared against purified bovine heart enzyme. Proteinase K treatment of mitoplasts converted the 110,000 transhydrogenase monomer into a single immunoreactive species having Mr 75,000. This proteolytic product is stable to further incubation with the protease. Treatment of submitochondrial particles with proteinase K resulted in the disappearance of the 110,000 monomer and the transient formation of an intermediate product with Mr 52,000. Information from these proteolysis studies was used to construct a model of the orientation of transhydrogenase in the inner mitochondrial membrane. This model indicates that transhydrogenase (Mr 110,000) contains a core of proteolytically inaccessible proteins within the membrane (Mr 23,000) bounded by extramembranous domains on the matrix (Mr 52,000) and cytoplasmic (Mr 35,000) face of the inner mitochondrial membrane.     

Regulation of mitochondrial morphology through proteolytic cleavage of OPA1

The dynamin-like GTPase OPA1, a causal gene product of human dominant optic atrophy, functions in mitochondrial fusion and inner membrane remodeling. It has several splice variants and even a single variant is found as several processed forms, although their functional significance is unknown. In yeast, mitochondrial rhomboid protease regulates mitochondrial function and morphology through proteolytic cleavage of Mgm1, the yeast homolog of OPA1. We demonstrate that OPA1 variants are synthesized with a bipartite-type mitochondrial targeting sequence. During import, the matrix-targeting signal is removed and processed forms (L-isoforms) are anchored to the inner membrane in type I topology. L-isoforms undergo further processing in the matrix to produce S-isoforms. Knockdown of OPA1 induced mitochondrial fragmentation, whose network morphology was recovered by expression of L-isoform but not S-isoform, indicating that only L-isoform is fusion-competent. Dissipation of membrane potential, expression of m-AAA protease paraplegin, or induction of apoptosis stimulated this processing along with the mitochondrial fragmentation. Thus, mammalian mitochondrial function and morphology is regulated through processing of OPA1 in a DeltaPsi-dependent manner.     

Multiple sites of proteolytic cleavage to release soluble forms of hepatocyte growth factor activator inhibitor type 1 from a transmembrane form.

Hepatocyte growth factor activator inhibitor type 1 (HAI-1) is a Kunitz-type serine protease inhibitor, which was identified as a potent inhibitor of hepatocyte growth factor (HGF) activator from the conditioned medium of a human carcinoma cell line. HGF activator is a blood coagulation factor XII-like serine protease that is responsible for proteolytic activation of the inactive single chain precursor of HGF in injured tissues. The predicted sequence of the primary translation product of HAI-1, which has a hydrophobic sequence in its COOH-terminal region, suggested that HAI-1 is first produced in a membrane-associated form. In this study, we identified a transmembrane form of HAI-1 integrated in the plasma membrane of cultured cells using a monoclonal antibody against HAI-1. We also identified several soluble forms of HAI-1 in the conditioned medium of the cells, indicating that multiple sites are present in the transmembrane form of HAI-1 at which proteolytic cleavage releases the extracellular domain. At least two proteases, one of which is a metalloprotease, appear to be responsible for the release. Further, the soluble forms of HAI-1 have different inhibitory activity against HGF activator. These findings suggest that proteolytic processing plays important roles in regulation of the inhibitory activity of HAI-1.     

The 5′-leader sequence of sugar beet mitochondrial <Emphasis Type="Italic">atp6</Emphasis> encodes a novel polypeptide that is characteristic of Owen cytoplasmic male sterility

Cytoplasmic male sterility (CMS) is a mitochondrially encoded trait, which is characterized by a failure of plants to produce viable pollen. We have investigated the protein profile of mitochondria from sugar beet plants with normal (fertile) or CMS cytoplasm, and observed that a 35-kDa polypeptide is expressed in Owen CMS plants but not in normal plants. The variant 35-kDa polypeptide was found in CMS mitochondria placed in five different nuclear backgrounds. Interestingly, this polypeptide proved to be antigenically related to a 387-codon ORF (preSatp6) that is fused in-frame with the downstream atp6. The presequence extension of the atp6 ORF is commonly found in higher plants, but whether or not it is normally expressed has hitherto remained unclear. Our study is thus the first to demonstrate that the atp6 presequence is actually translated in mitochondria. We also observed that preSATP6 is a mitochondrial membrane protein that assembles into a homogeneous 200-kDa protein complex. In organello translation experiments in the presence of protease inhibitors showed a reduction in the abundance of mature preSATP6 with time, suggesting that the mature preSATP6 may be derived by proteolytic processing of a translation product of the preSatp6/Satp6 ORF.     

Intramitochondrial fatty acylation of a cytoplasmic imported protein in animal cells

Mitochondrial digitonin particles from mouse liver (and also from other tissues) incorporate [3H]myristic acid into a 52-kilodalton (kDa) protein in an energy-dependent manner. The 52-kDa N-myristylated protein is located inside the mitochondrial inner membrane since it is protected against proteolytic degradation in intact mitoplasts. Disruption of mitochondrial inner membrane by sonication results in severalfold higher labeling of the 52-kDa protein, further confirming that the enzyme system for protein fatty acylation as well as the 52-kDa target protein are compartmentalized inside the mitochondrial inner membrane matrix. The results of in vitro labeling of submitochondrial fractions suggest that both the 52-kDa target protein and the enzyme system for fatty acylation are in the matrix fraction, although the N-myristylated protein is found loosely associated with the inner membrane. Finally, immunoprecipitation of cytoplasmic free polysome translation products and in vitro transport of proteins into isolated mitochondria show that the 52-kDa protein is of cytoplasmic translation origin. These results demonstrate that the intramitochondrial N-myristylation of the 52-kDa protein is not translationally linked.     

AAA proteases with catalytic sites on opposite membrane surfaces comprise a proteolytic system for the ATP-dependent degradation of inner membrane proteins in mitochondria.

The mechanism of selective protein degradation of membrane proteins in mitochondria has been studied employing a model protein that is subject to rapid proteolysis within the inner membrane. Protein degradation was mediated by two different proteases: (i) the m-AAA protease, a protease complex consisting of multiple copies of the ATP-dependent metallopeptidases Yta1Op (Afg3p) and Yta12p (Rcalp); and (ii) by Ymelp (Ytallp) that also is embedded in the inner membrane. Ymelp, highly homologous to Yta1Op and Yta12p, forms a complex of approximately 850 kDa in the inner membrane and exerts ATP-dependent metallopeptidase activity. While the m-AAA protease exposes catalytic sites to the mitochondrial matrix, Ymelp is active in the intermembrane space. The Ymelp complex was therefore termed 'i-AAA protease'. Analysis of the proteolytic fragments indicated cleavage of the model polypeptide at the inner and outer membrane surface and within the membrane-spanning domain. Thus, two AAA proteases with their catalytic sites on opposite membrane surfaces constitute a novel proteolytic system for the degradation of membrane proteins in mitochondria.     

Rubella virus nonstructural protein protease domains involved in trans- and cis-cleavage activities

Rubella virus (RV) genomic RNA contains two large open reading frames (ORFs): a 5'-proximal ORF encoding nonstructural proteins (NSPs) that function primarily in viral RNA replication and a 3'-proximal ORF encoding the viral structural proteins. Proteolytic processing of the RV NSP ORF translation product p200 is essential for viral replication. Processing of p200 to two mature products (p150 and p90) in the order NH(2)-p150-p90-COOH is carried out by an RV-encoded protease residing in the C-terminal region of p150. The RV nonstructural protease (NS-pro) belongs to a viral papain-like protease family that cleaves the polyprotein both in trans and in cis. A conserved X domain of unknown function was found from previous sequence analysis to be associated with NS-pro. To define the domains responsible for cis- and trans-cleavage activities and the function of the X domain in terms of protease activity, an in vitro translation system was employed. We demonstrated that the NSP region from residue 920 to 1296 is necessary for trans-cleavage activity. The domain from residue 920 to 1020 is not required for cis-cleavage activity. The X domain located between residues 834 and 940, outside the regions responsible for both cis- and trans-cleavage activities of NS-pro, was found to be important for NS-pro trans-cleavage activity but not for cis-cleavage activity. Analysis of sequence homology and secondary structure of the RV NS-pro catalytic region reveals a folding structure similar to that of papain.     

Differential expression of cysteine proteases in developmental stages of the parasitic ciliate Ichthyophthirius multifiliis

An expressed sequence tag database of the freshwater fish parasite, Ichthyophthirius multifiliis (Ciliophora) was analyzed to seek for proteases potentially involved in the invasion and degradation of host tissues during infection. The translation of the database revealed two cathepsin L cysteine proteases (Icp1 and Icp2) of the C1A peptidase subfamily. The analysis of Icp1 and Icp2 sequences suggested that both proteases would be synthesized as preproproteins, with a mature domain of 27.9 and 22.8 kDa, respectively. Their expression level was determined in the trophont parasitic stage, in the tomont reproductive stage, and in the theront infective stage by real-time RT-PCR. ICP1 and ICP2 were significantly upregulated in trophont and theront stages in comparison with the tomont stage. Mature peptides of Icp1 and Icp2 were identified in crude extracts of I. multifiliis trophonts by LC-MS/MS. Zymograms showed three to seven activity bands at the optimum pH of cathepsin L cysteine proteases. Two bands displaying cysteine protease activity were identified by inhibition with E-64. They represented the major proteolytic activity of the trophont stage at pH 5-7, suggesting that cysteine proteases play an important role in the infection process.     

Proteolytic activity of subcellular fractions from Streptomyces griseus no. 45-H.

Subcellular fractions were prepared from Streptomyces griseus No. 45-H at different stages of life cycle, and their proteolytic activity was examined. The highest proteolytic activity was found in the 24- and 72- h-old vegetative hyphae, the lowest in the resting spores. Spores contained about 9--30% of the proteolytic activity of vegetative cells. At the age of 16 h about 80%, at 26 h 70%, at 72 h 40%, and in spores about 60% of the proteolytic activity was particulate. The greatest part of the proteolytic activity could be inhibited by EDTA, lower levels of serine and sulfhydryl protease activities were detected in the cell-free extracts of vegetative cells.     

Translation-coupled translocation of yeast fumarase into mitochondria in vivo

Fumarase represents proteins that cannot be imported into mitochondria after the termination of translation (post-translationally). Utilizing mitochondrial and cytosolic versions of the tobacco etch virus (TEV) protease, we show that mitochondrially targeted fumarase harboring a TEV protease recognition sequence is efficiently cleaved by the mitochondrial but not by the cytosolic TEV protease. Nonetheless, fumarase was readily cleaved by cytosolic TEV when its import into mitochondria was slowed down by either (i) disrupting the activity of the TOM complex, (ii) lowering the growth temperature, or (iii) reducing the inner membrane electrochemical potential. Accessibility of the fumarase nascent chain to TEV protease under such conditions was prevented by low cycloheximide concentrations, which impede translation. In addition, depletion of the ribosome-associated nascent polypeptide-associated complex (NAC) reduced the fumarase rate of translocation into mitochondria and exposed it to TEV cleavage in the cytosol. These results indicate that cytosolic exposure of the fumarase nascent chain depends on both translocation and translation rates, allowing us to discuss the possibility that import of fumarase into mitochondria occurs while the ribosome is still attached to the nascent chain.     

The plant mitochondrial open reading frame orf221 encodes a membrane-bound protein

We have shown that the open reading frame orf221 is an active mitochondrial gene which encodes a novel mitochondrial polypeptide. The orf221 sequence is common to higher plants but absent in animal and fungal mitochondria. A mitochondrial polypeptide with an apparent molecular weight of 21 000 was detected with a polyclonal antibody raised against an ORF221 fusion protein. In organello translation followed by immunoprecipitation with the anti-ORF221 antibody demonstrated that this polypeptide is encoded by the orf221 gene in plant mitochondria. The ORF221 was found to be a mitochondrial membrane protein in normal (N), cms-T, and cms-C cytoplasms of several inbred lines of maize (Zea mays L.) and in other plant species.