The flowering process in plants proceeds through the induction of an inflorescence meristem triggered by several pathways. Many of the genes associated with these pathways encode transcription factors of the MADS domain family. The MADS-domain transcription factor APETALA1 (AP1) is a key regulator of flower development. The first step to understand the molecular mechanisms under the function of each gene in a plant is identification, sequencing and phylogeny analysis of that gene. For this purpose, total RNA was isolated from flower bud of garden cress (Lepidium sativum L.) and was used for cDNA synthesis. The specific primers were designed based on nucleotide sequence alignment of AP1 homologus genes from plants of the same family Brassicaceae and were used in RT-PCR. After observing its electrophoretic pattern and ensuring the quality of PCR product, the amplicon was sent for sequencing. After receiving the results of sequencing, the sequence examined with BLAST, MUSCLE, Gene Runner and MEGA6 softwares. The results indicated amplification of 787 nucleotides fragment that named LsAP1 and was recorded by accession number KP070728 in NCBI database. The studies show high similarity and overlapping of gene bank sequences with LsAP1 illative protein. According to these results, LsAP1 may play a similar role as AP1 in flower induction and could act as a flower meristem identity gene in Lepidium sativum L.

Cutin is a polymer that is constructed in plants by the condensation and oxidation of fatty acids and plays a key role in the protection of plants against pathogens. Cutinase is a hydrolase enzyme that breaks down the cutin. The purpose of this study was to extract cutin from red apples with oxalate buffer, cutinase enzyme activity assay in LB culture, and bioinformatic analysis. To attain these purposes the cutinase-producing strains that had previously been isolated were inoculated in culture medium containing cutin. After initial culture, the bacteria were cultured in LB medium and cutinase activity was measured using the p-Nitrophenyl butyrate. In order to execute bioinformatic analysis, the isolated sequences of six cutinase-producing bacteria were analyzed based on computational data bases and their phylogenetic trees were prepared. Then, the similarities in the sequences of a large number of cutinase-producing samples were analyzed by drawing the phylogenetic tree. The results showed the separation of cutinase-producing prokaryotes from cutinase-producing eukaryotes. Then, the sequence of 16S rDNA of these cutinase-producing samples as well as the samples we had prepared were evaluated and their phylogenetic relationships were determined. This analysis showed that the new sequence stood alongside the bacterial samples. Thus, our cutinases may be similar with these bacterial cutinases in structure and function.