PIP1 Aquaporins Are Concentrated in Plasmalemmasomes of Arabidopsis thaliana Mesophyll.

The PIP1 subfamily of water channel proteins (aquaporins) constitute about 1% of the plasma membrane (PM) proteins from Arabidopsis thaliana leaves. Immunogold electron microscopy has confirmed their localization at the PM of mesophyll cells. Very high labeling density at PM invaginations known as plasmalemmasomes was observed. Therefore, we suggest that these subcellular structures are involved in water transport between the apoplast and the vacuole.

Water channels in the plant plasma membrane cloned by immunoselection from a mammalian expression system.

Expression in mammalian COS cells and an efficient microtiter-based strategy for immunoselection was used in a novel approach to identify genes encoding plant membrane proteins. COS cells were transfected with an Arabidopsis thaliana root cDNA library constructed in a bacterial mammalian shuttle vector and screened with an antiserum raised against purified deglycosylated integral plasma membrane proteins from A. thaliana roots. Antibodies directed against a prominent 27 kDa antigen led to the identification of five different genes. They comprised two subfamilies related to the major intrinsic protein (MIP) superfamily and were named plasma membrane intrinsic proteins, PIP1 and PIP2, since the cellular localization of PIP1 and most probably PIP2 proteins in the plasma membrane was independently confirmed by their cosegregation with marker enzymes during aqueous two-phase partitioning. Surprisingly, expression in Xenopus laevis oocytes revealed that all five PIP mRNAs coded for Hg(2+)-sensitive water transport facilitating activities. There had been no previous evidence of the existence of water channels in the plasma membrane of plant cells and the high diffusional water permeability of the lipid bilayer was considered to be sufficient for water exchange. Nevertheless, Northern and Western analyses showed that the PIP genes are constitutively and possibly even redundantly expressed from the small A. thaliana genome.

Isolation and properties of a nitrile hydratase from the soil fungus Myrothecium verrucaria that is highly specific for the fertilizer cyanamide and cloning of its gene.

A protein was purified from crude extracts of the soil fungus Myrothecium verrucaria by gel filtration and hydrophobic chromatography to homogeneity; this protein catalyzed the stoichiometric hydration of the fertilizer cyanamide to urea with high substrate specificity. This cyanamide hydratase (urea hydro-lyase; EC 4.2.1.69) contained zinc and consisted of six identical subunits with Mr = 27,700. It was partially sequenced. The protein was detectable only when the fungus was grown on cyanamide as the sole nitrogen source. Genomic DNA from the fungus was cloned, and the gene encoding the enzyme was mapped with an oligonucleotide probe derived from the amino acid sequence within a 25,800-base-pair DNA region. The subunit of the enzyme is encoded by a 795-base-pair DNA sequence containing a 63-base-pair intron. A cDNA clone containing the intronless gene with an open reading frame encoding a sequence of 244 amino acids expressed the enzyme in active form in Escherichia coli with excellent yield.