Climate change poses a significant challenge to agriculture while barley is an essential and crucial crop worldwide. This study evaluated the drought stress tolerance of 25 barley genotypes. A field experiment was carried out to investigate agronomical traits, such as plant height at 110 days (PH110) and spike length (SL), in response to different surface irrigation treatments. Subsequently, 15 barley genotypes were chosen for the second experiment which aimed to examine the impact of physiological stress generated by polyethylene glycol-6000. Several biological metrics, including seedling vigor index (SVI), and drought tolerance index (DTI), were quantified. Ultimately, six SSR primers were used to analyze the genetic diversity between different barley genotypes. The findings demonstrated that the G1, G2, and G6 genotypes were tolerant but G5, G9, and G14 were susceptible. The primers Bmag0603, EBmac0849, and Bmag770 were polymorphic. This study provides valuable initial insights into the drought resistance of various barley genotypes, highlighting the genetic diversity and potential for breeding drought-tolerant varieties. We suggest expanding the sample size and incorporating a broader range of environmental conditions in future studies to validate these findings. Additionally, the identified genetic markers could be further explored and utilized in breeding programs.

Drought stress is considered one of the main factors that reduce plant growth, development and production. Therefore, studying plants during drought stress is highly useful to discover the newly gained characteristics of plants. The potato is considered one of the most important crop with economic value in Egypt and over the whole world. The main target is the proline-rich protein extracted from potato plants under drought stress. A stress experiment was applied to two potato (Solanum tuberosum L.) cultivars Desiree and Diamante. The stress experiment was conducted by poly-ethylene glycol (PEG) 4000; the used water potentials were: zero (control), (PEG 2%), (PEG 4%) and (PEG 8%), after drought stress, the solutes accumulation in the two potato cultivars were determined. Increasing drought stress through elevating PEG decreased leaf area as well as shoot and root lengths. Incontorary, the chlorophyll and proline contents increased with increasing PEG treatments. The proline-rich protein gene was cloned to the pGEM-T Easy vector and was submitted to the gene bank to be used later for enhancing drought resistance in other cultivars.

Drought stress is considered one of the main factors that reduce plant growth, development and production. Therefore, studying plants during drought stress is highly useful to discover the newly gained characteristics of plants. The potato is considered one of the most important crop with economic value in Egypt and over the whole world. The main target is the proline-rich protein extracted from potato plants under drought stress. A stress experiment was applied to two potato (Solanum tuberosum L.) cultivars Desiree and Diamante. The stress experiment was conducted by poly-ethylene glycol (PEG) 4000; the used water potentials were: zero (control), (PEG 2%), (PEG 4%) and (PEG 8%), after drought stress, the solutes accumulation in the two potato cultivars were determined. Increasing drought stress through elevating PEG decreased leaf area as well as shoot and root lengths. Incontorary, the chlorophyll and proline contents increased with increasing PEG treatments. The proline-rich protein gene was cloned to the pGEM-T Easy vector and was submitted to the gene bank to be used later for enhancing drought resistance in other cultivars.

Climate change poses a significant challenge to agriculture while barley is an essential and crucial crop worldwide. This study evaluated the drought stress tolerance of 25 barley genotypes. A field experiment was carried out to investigate agronomical traits, such as plant height at 110 days (PH110) and spike length (SL), in response to different surface irrigation treatments. Subsequently, 15 barley genotypes were chosen for the second experiment which aimed to examine the impact of physiological stress generated by polyethylene glycol-6000. Several biological metrics, including seedling vigor index (SVI), and drought tolerance index (DTI), were quantified. Ultimately, six SSR primers were used to analyze the genetic diversity between different barley genotypes. The findings demonstrated that the G1, G2, and G6 genotypes were tolerant but G5, G9, and G14 were susceptible. The primers Bmag0603, EBmac0849, and Bmag770 were polymorphic. This study provides valuable initial insights into the drought resistance of various barley genotypes, highlighting the genetic diversity and potential for breeding drought-tolerant varieties. We suggest expanding the sample size and incorporating a broader range of environmental conditions in future studies to validate these findings. Additionally, the identified genetic markers could be further explored and utilized in breeding programs.