Microscopic and molecular genetic analyses of morphological development of the actinomycete Actinoplanes missouriensis.

The survival strategy of members of the bacterial genus Actinoplanes is fascinating from morphological and evolutionary perspectives. A brief motile phase is incorporated in the filamentous and resting stages of the life cycle of Actinoplanes missouriensis. Spores either lie dormant or swim under different external conditions. This review presents microscopic observations and molecular genetic analyses of A. missouriensis morphological development. Selected examples of the characterization of developmental genes and their products are also introduced.

Involvement of a putative acyltransferase gene in sporangium formation in Actinoplanes missouriensis.

The actinomycete Actinoplanes missouriensis forms branched substrate mycelia during vegetative growth and produces terminal sporangia, each of which contains a few hundred spherical flagellated spores, from the substrate mycelia through short sporangiophores. Based on the observation that remodeling of membrane lipid composition is involved in the morphological development of Streptomyces coelicolor A3(2), we hypothesized that remodeling of membrane lipid composition is also involved in sporangium formation in A. missouriensis. Because some acyltransferases are presumably involved in the remodeling of membrane lipid composition, we disrupted each of the 22 genes annotated as encoding putative acyltransferases in the A. missouriensis genome and evaluated their effects on sporangium formation. The atsA (AMIS_52390) null mutant (ΔatsA) strain formed irregular sporangia of various sizes. Transmission electron microscopy revealed that some ΔatsA sporangiospores did not mature properly. Phase-contrast microscopy revealed that sporangium dehiscence did not proceed properly in the abnormally small sporangia of the ΔatsA strain, whereas apparently normal sporangia opened to release the spores. Consistently, the number of spores released from ΔatsA sporangia was lower than that released from wild-type sporangia. These phenotypic changes were recovered by introducing atsA with its own promoter into the ΔatsA strain. These results demonstrate that AtsA is required for normal sporangium formation in A. missouriensis, although the involvement of AtsA in the remodeling of membrane lipid composition is unlikely because AtsA is an acyltransferase_3 (AT3) protein, which is an integral membrane protein that usually catalyzes the acetylation of cell surface structures.IMPORTANCEActinoplanes missouriensis goes through a life cycle involving complex morphological development, including mycelial growth, sporangium formation and dehiscence, swimming as zoospores, and germination to mycelial growth. In this study, we carried out a comprehensive gene disruption experiment of putative acyltransferase genes to search for acyltransferases involved in the morphological differentiation of A. missouriensis. We revealed that a stand-alone acyltransferase_3 domain-containing protein, named AtsA, is required for normal sporangium formation. Although the molecular mechanism of AtsA in sporangium formation, as well as the enzymatic activity of AtsA, remains to be elucidated, the identification of a putative acyltransferase involved in sporangium formation is significant in the study of morphological development of A. missouriensis. This finding will contribute to our understanding of a complex system for producing sporangia, a rare multicellular organism in bacteria.

Identification of a putative cell wall-hydrolyzing amidase involved in sporangiospore maturation in Actinoplanes missouriensis.

Actinoplanes missouriensis is a filamentous bacterium that differentiates into terminal sporangia, each containing a few hundred spores. Previously, we reported that a cell wall-hydrolyzing N-acetylglucosaminidase, GsmA, is required for the maturation process of sporangiospores in A. missouriensis; sporangia of the gsmA null mutant (ΔgsmA) strain released chains of 2-20 spores under sporangium dehiscence-inducing conditions. In this study, we identified and characterized a putative cell wall hydrolase (AsmA) that is also involved in sporangiospore maturation. AsmA was predicted to have a signal peptide for the general secretion pathway and an N-acetylmuramoyl-l-alanine amidase domain. The transcript level of asmA increased during the early stages of sporangium formation. The asmA null mutant (ΔasmA) strain showed phenotypes similar to those of the wild-type strain, but sporangia of the ΔgsmAΔasmA double mutant released longer spore chains than those from the ΔgsmA sporangia. Furthermore, a weak interaction between AsmA and GsmA was detected in a bacterial two-hybrid assay using Escherichia coli as the host. Based on these results, we propose that AsmA is an enzyme that hydrolyzes peptidoglycan at septum-forming sites to separate adjacent spores during sporangiospore maturation in cooperation with GsmA in A. missouriensis.IMPORTANCEActinoplanes missouriensis produces sporangiospores as dormant cells. The spores inside the sporangia are assumed to be formed from prespores generated by the compartmentalization of intrasporangium hyphae via septation. Previously, we identified GsmA as a cell wall hydrolase responsible for the separation of adjacent spores inside sporangia. However, we predicted that an additional cell wall hydrolase(s) is inevitably involved in the maturation process of sporangiospores because the sporangia of the gsmA null mutant strain released not only tandemly connected spore chains (2-20 spores) but also single spores. In this study, we successfully identified a putative cell wall hydrolase (AsmA) that is involved in sporangiospore maturation in A. missouriensis.

The ssgB gene is required for the early stages of sporangium formation in Actinoplanes missouriensis.

In Streptomyces, multiple paralogs of SsgA-like proteins (SALPs) are involved in spore formation from aerial hyphae. However, the functions of SALPs have not yet been elucidated in other actinobacterial genera. Here, we report the primary function of an SsgB ortholog (AmSsgB) in Actinoplanes missouriensis, which develops terminal sporangia on the substrate mycelia via short sporangiophores. Importantly, AmSsgB is the sole SALP in A. missouriensis. The transcription of AmssgB was upregulated during sporangium formation, consistent with our previous findings that AmssgB is a member of the AmBldD regulon. The AmssgB null mutant (ΔAmssgB) strain formed non-globose irregular structures on the substrate mycelium. Transmission electron microscopy revealed that the irregular structures contained abnormally septate hypha-like cells, without an intrasporangial matrix. These phenotypic changes were restored by complementation with AmssgB. Additionally, analysis of the heterologous expression of seven SALP-encoding genes from Streptomyces coelicolor A3(2) (ssgA-G) in the ΔAmssgB strain revealed that only ssgB could compensate for AmSsgB deficiency. This indicated that SsgB of S. coelicolor A3(2) and AmSsgB have comparable functions in A. missouriensis. In contrast to the ΔAmssgB strain, the ftsZ-disrupted strain showed a severe growth defect and produced small sporangium-like structures that swelled to some extent. These findings indicate that AmSsgB is crucial for the early stages of sporangium formation, not for spore septum formation in the late stages. We propose that AmSsgB is involved in sporangium formation by promoting the expansion of the "presporangium" structures formed on the tips of the substrate hyphae. IMPORTANCE: SsgB has been proposed as an archetypical SsgA-like protein with an evolutionarily conserved function in the morphological development of spore-forming actinomycetes. SsgB in Streptomyces coelicolor A3(2) is involved in spore septum formation. However, it is unclear whether this is the primary function of SsgBs in actinobacteria. This study demonstrated that the SsgB ortholog (AmSsgB) in Actinoplanes missouriensis is essential for sporangium expansion, which does not seem to be related to spore septum formation. However, the heterologous expression of ssgB from S. coelicolor A3(2) restored morphological abnormalities in the ΔAmssgB mutant. We propose that the primary function of SsgB is to initiate sporulation in differentiating cells (e.g., aerial hyphae in Streptomyces and "presporangium" cells in A. missouriensis) although its molecular mechanism remains unknown.

Architecture of Actinoplanes missouriensis sporangia and zoospores visualized using quick-freeze deep-etch electron microscopy.

The architecture of sporangia and zoospores of Actinoplanes missouriensis was analyzed at a high resolution using quick-freeze deep-etch replica electron microscopy. This analysis revealed that (i) sporangia were surrounded by at least 2 membranous layers with smooth surfaces, (ii) zoospores were enclosed by a fibrillar layer, and (iii) flagella were generated in a restricted area on the zoospore surface.

Surface structure and nanomechanical properties of Actinoplanes missouriensis sporangia analyzed via atomic force microscopy.

The surface structures of the sporangia produced by Actinoplanes missouriensis were analyzed at high resolution in air and liquid via atomic force microscopy. Results revealed a dynamic change in sporangium surface structure in response to the amount of moisture. Furthermore, the Young's modulus of the sporangium surface (1.95 ± 0.92 GPa) was calculated by analyzing the force-distance curves in air.

Isolation of a novel plasmid from Couchioplanes caeruleus and construction of two plasmid vectors for gene expression in Actinoplanes missouriensis.

To date, no plasmid vector has been developed for the rare actinomycete Actinoplanes missouriensis. Moreover, no small circular plasmid has been reported to exist in the genus Actinoplanes. Here, a novel plasmid, designated pCAZ1, was isolated from Couchioplanes caeruleus subsp. azureus via screening for small circular plasmids in Actinoplanes (57 strains) and Couchioplanes (2 strains). Nucleotide sequencing revealed that pCAZ1 is a 5845-bp circular molecule with a G + C content of 67.5%. The pCAZ1 copy number was estimated at 30 per chromosome. pCAZ1 contains seven putative open reading frames, one of which encodes a protein containing three motifs conserved among plasmid-encoded replication proteins that are involved in the rolling-circle mechanism of replication. Detection of single-stranded DNA intermediates in C. caeruleus confirmed that pCAZ1 replicates by this mechanism. The ColE1 origin from pBluescript SK(+) and the oriT sequence with the apramycin resistance gene aac(3)IV from pIJ773 were inserted together into pCAZ1, to construct the Escherichia coli-A. missouriensis shuttle vectors, pCAM1 and pCAM2, in which the foreign DNA fragment was inserted into pCAZ1 in opposite directions. pCAM1 and pCAM2 were successfully transferred to A. missouriensis through the E. coli-mediated conjugative transfer system. The copy numbers of pCAM1 and pCAM2 in A. missouriensis were estimated to be one and four per chromosome, respectively. Thus, these vectors can be used as effective genetic tools for homologous and heterologous gene expression studies in A. missouriensis.