AtSig5 is an essential nucleus-encoded Arabidopsis sigma-like factor.

Transcription of chloroplast genes is subject to control by nucleus-encoded proteins. The chloroplast-encoded RNA polymerase (PEP) is a eubacterial-type RNA polymerase that is presumed to assemble with nucleus-encoded sigma-factors mediating promoter recognition. Recently, families of sigma-factor genes have been identified in several plants including Arabidopsis. One of these genes, Arabidopsis SIG5, encodes a sigma-factor, AtSig5, which is phylogenetically distinct from the other family members. To investigate the role of this plant sigma-factor, two different insertional alleles of the SIG5 gene were identified and characterized. Heterozygous mutant plants showed no visible leaf phenotype, but exhibited siliques containing aborted embryos and unfertilized ovules. Our inability to recover plants homozygous for a SIG5 gene disruption indicates that SIG5 is an essential gene. SIG5 transcripts accumulate in flower tissues, consistent with a role for AtSig5 protein in reproduction. Therefore, SIG5 encodes an essential member of the Arabidopsis sigma-factor family that plays a role in plant reproduction in addition to its previously proposed role in leaf chloroplast gene expression.

A nucleus-encoded maize protein with sigma factor activity accumulates in mitochondria and chloroplasts.

Plants contain nuclear gene families that encode proteins related to the principal sigma factors of eubacteria. As sigma factors function in transcription, the plant proteins have been presumed or demonstrated to associate with the eubacteria-like RNA polymerase of chloroplasts. In maize, five sig cDNA sequences have been reported, and four of the products are present in plastids as predicted. However, in vitro chloroplast import assays and computer algorithms gave ambiguous results with the fifth protein, ZmSig2B. Unlike the other maize sigma factors, ZmSig2B is expressed throughout developing seedling leaves, as well as in roots and etiolated tissues. To determine the subcellular location of ZmSig2B, we have now used immunoblot assays to show that it co-purifies with both mitochondria and plastids. Its NH2-terminal 153 amino acids, translationally fused to green fluorescent protein (GFP), targeted GFP to chloroplasts and mitochondria in bombarded maize leaves. A putative role for ZmSig2B in mitochondrial transcription is supported by its presence in a maize mitochondrial transcription extract. ZmSig2B also exhibits the expected properties of a chloroplast sigma factor: recombinant ZmSig2B binds to a chloroplast promoter and initiates transcription in vitro when combined with Escherichia coli core RNA polymerase. Therefore ZmSig2B is an unusual nucleus-encoded sigma factor that appears to function in both chloroplasts and mitochondria.