A method of expressing an agronomically or non-agronomically beneficial trait in a plant plastid comprising expressing an exogenous nucleic acid in the plant to produce non-photosynthetic mutant plants, and using callus grown from the mutant plants as recipients for introduction of a construct having a functional copy of the mutated gene and a gene conferring an agronomically or non-agronomically beneficial trait. Embodiments provide for mutations in chloroplast-encoded genes, as well as mutations in nuclear-encoded genes targeted to the chloroplast that are required for photosynthesis, plants and plant parts produced from such methods, as well as kits for performing the methods as described.

This disclosure provides a number of sequences involved in nitrogen utilization, methods of using such sequences, tobacco plants carrying modifications to such sequences, tobacco plants transgenic for such sequences, and tobacco products made from such plants.

This invention relates to genetically modified plants with improved drought tolerance and to genetically modified cells thereof. These plants may have thicker leaves, rounder leaf shape or higher chlorophyll content. The plants may be modified to increase the expression of a plant calmodulin-binding protein IQD22, IQD23 or IQD24. The modified plants are expected to have improved yields under variable field conditions. The invention also relates to a method of genetically modifying a plant to have these characteristics. The invention further relates to isolated nucleic acids and polynucleotide constructs for the genetic engineering of such plants and their use.

Aspects of the present disclosure relate to genetically altered plants with enhanced biomass including genetic alterations that stimulate RubP regeneration and electron transport. In particular, the present disclosure relates to genetically altered plants with enhanced biomass through overexpression of CB proteins (e.g., FBPase/SBPase or SBPase), and overexpression of photosynthetic electron transport proteins (e.g., cytochrome c.sub.6 and Rieske FeS).

Provided herein are novel thermostable phycobiliproteins. These proteins may be stabilized by the introduction of disulfide bonds which stabilize the protein. Modified cells expressing these thermostable phycobiliproteins and methods of making them are also provided.

Compositions and methods for modifying genomic DNA sequences are provided. The methods produce double-stranded breaks (DSBs) at pre-determined target sites in a genomic DNA sequence, resulting in mutation, insertion, and/or deletion of DNA sequences at the target site(s) in a genome. Compositions comprise DNA constructs comprising nucleotide sequences that encode a Cms1 protein operably linked to a promoter that is operable in the cells of interest. The DNA constructs can be used to direct the modification of genomic DNA at pre-determined genomic loci. Methods to use these DNA constructs to modify genomic DNA sequences are described herein. Additionally, compositions and methods for modulating the expression of genes are provided. Compositions comprise DNA constructs comprising a promoter that is operable in the cells of interest operably linked to nucleotide sequences that encode a mutated Cms1 protein with an abolished ability to produce DSBs, optionally linked to a domain that regulates transcriptional activity. The methods can be used to up- or down-regulate the expression of genes at predetermined genomic loci.

This disclosure provides tobacco plants that exhibit altered photosynthesis as well as methods of making and using such plants.

A genetically engineered land plant that expresses a protein that has homology to a plant invertase inhibitor and/or a pectin methylesterase inhibitor and that increases seed yield with increased expression (“an ISY protein”) is disclosed. The plant comprises a modified gene for the ISY protein. The ISY protein comprises one or more of an ISY protein of Camelina sativa comprising SEQ ID NO: 2 or a fragment, Camelina sativa homolog, or ortholog thereof. The modified gene comprises a promoter and a nucleic acid sequence encoding the ISY protein. The promoter is non-cognate with respect to the nucleic acid sequence encoding the ISY protein. The modified gene is configured such that transcription of the nucleic acid sequence is initiated from the promoter and results in expression of the ISY protein. A genetically engineered land plant that expresses an RNA that increases seed yield with increased expression also is disclosed.

The invention provides methods of transforming photosynthetic organisms, such as green algae. The methods involve methylating one or more DNA fragments of a DNA construct and transforming the one or more fragments into the photosynthetic organism. The DNA fragments can be the product of a DNA amplification procedure, such as PCR or a PCR-like procedure. In one embodiment the one or more fragments of DNA that comprise a DNA construct are dam methylated prior to being transformed into the photosynthetic organism.

Disclosed herein are mutant photosynthetic microorganisms having an attenuated SGI1 gene. The mutants have reduced chlorophyll and increased productivity with respect to wild type cells. Also disclosed are methods of using such mutants for producing biomass or bioproducts, and methods of screening for such mutants.