Abstract

Spaceflight microgravity affects normal plant growth in several ways. The transcriptional dataset of the plant model organism Arabidopsis thaliana grown in the international space station is mined using graph-theoretic network analysis approaches to identify significant gene transcriptions in microgravity essential for the plant’s survival and growth in altered environments. The photosynthesis process is critical for the survival of the plants in spaceflight under different environmentally stressful conditions such as lower levels of gravity, lesser oxygen availability, low atmospheric pressure, and the presence of cosmic radiation. Lasso regression method is used for gene regulatory network inferencing from gene expressions of four different ecotypes of Arabidopsis in spaceflight microgravity related to the photosynthetic process. The individual behavior of hub-genes and stress response genes in the photosynthetic process and their impact on the whole network is analyzed. Logistic regression on centrality measures computed from the networks, including average shortest path, betweenness centrality, closeness centrality, and eccentricity, and the HITS algorithm is used to rank genes and identify interactor or target genes from the networks. Through the hub and authority gene interactions, several biological processes associated with photosynthesis and carbon fixation genes are identified. The altered conditions in spaceflight have made all the ecotypes of Arabidopsis sensitive to dehydration-and-salt stress. The oxidative and heat-shock stress-response genes regulate the photosynthesis genes that are involved in the oxidation-reduction process in spaceflight microgravity, enabling the plant to adapt successfully to the spaceflight environment.

Highlights

  • Arabidopsis thaliana (Arabidopsis), a member of the Brassicaceae or mustard family, is a small photosynthetic plant that requires only light, air, water, and few minerals for its survival

  • The hub-genes act as transcription factors (TFs) that regulate other target genes in the Gene Regulatory Networks (GRN)

  • The common hub-genes of all the ecotypes in spaceflight microgravity and ground control related to photosynthetic GRN are DRT112, ATRFNR2, PSAK, PSB27, ATFD1, PSAF, ATLFNR2, ATPC2, PSAO

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Summary

Introduction

Arabidopsis thaliana (Arabidopsis), a member of the Brassicaceae or mustard family, is a small photosynthetic plant that requires only light, air, water, and few minerals for its survival. It occupies minimal space and can be quickly grown in an indoor growth chamber. Arabidopsis has several ecotypes/natural variants, and these variations can sometimes be visible in physical traits when they are grown under different environmental stressors on the ground. Besides exploring natural genetic variants of Arabidopsis under different environmental stressors, the genetic factors causing physiological variations are mostly unknown [3]. The genetic basis of responses of different ecotypes/natural variants of Arabidopsis under different environmental stressors such as hypoxia, light, dark, salt, drought, 4.0/)

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