The chloroplast, with a small genome, can encode only 2% of its total proteins, while the majority are encoded by the nucleus. The import of thousands of cytosolic proteins is mediated by TOC and TIC (Translocon at the Outer membrane/Translocon at the Inner membrane of Chloroplast) complexes. It has been proposed that a TIC 1MDa complex includes proteins encoded by the nucleus (TIC100, TIC56, and TIC20) and the chloroplast (TIC214). Arabidopsis cue8 (carrying a mutation in TIC100) was originally identified as a virescent mutant, defective in chloroplast development. The current study has revealed activation of a compensatory mechanism by the partial loss of function in cue8, to support chloroplast gene expression. This homeostasis mechanism includes elevation of expression of nucleus-encoded plastid RNA polymerase (NEP) genes, maintenance of chloroplast DNA replication in spite of the defect, and modulation of expression of sigma factors. The finding provides an explanation for delayed chloroplast differentiation (virescence) and highlights importance of chloroplast-to-nucleus communication, revealing the fitness advantage it confers. The phenotypic difference in cue8 plants can be explained by reduction of GLK transcription factors. However, simple overexpression of GLK1, GLK2, or FC1, the known source of a positive chloroplast-to-nucleus signal, fails to rescue the cue8 defect. A forward genetic screen for suppressors of cue8 resulted in identification of an intragenic suppressor that demonstrates the role of TIC100 in translocation of cytosolic proteins across the chloroplast inner membrane, and necessity of the 1MDa TIC complex in the import of both photosynthetic and housekeeping proteins. A developing wheat leaf (with its white base and its green tip) is a model system to observe and quantify the extent of plastid development in the cells, its individual processes, and the associated gene expression program. A thorough analysis of the greening wheat leaf, through quantitative microscopy and high-throughput gene expression data, has contributed to understanding the sequence of processes occurring during chloroplast biogenesis, including growth, division, chloroplast DNA replication, gene expression, protein import, and greening. The current study distinguishes various phases of chloroplast development and explains how defects in plastid protein import affect a specific phase. The unique combination of investigations in Arabidopsis and wheat has contributed to an overall understanding of plastid biogenesis and extends the scope of search for novel candidate regulators of chloroplast development.