https://notaspampeanas.com/tags/plant-anatomy/ Recent content in Plant Anatomy on Notaspampeanas Hugo -- gohugo.io en © 2026 Notaspampeanas Tue, 02 Jun 2026 00:12:24 -0300 https://notaspampeanas.com/posts/1767106852444-sequia-plantas/ Tue, 02 Jun 2026 00:12:24 -0300 https://notaspampeanas.com/posts/1767106852444-sequia-plantas/ <p> <figure> <img class="my-0 rounded-md" loading="lazy" srcset=" /img/banner_Picadas_740x90_hu6243832387006456068.gif 330w, /img/banner_Picadas_740x90_hu16658372186798142604.gif 660w, /img/banner_Picadas_740x90_hu2999609979724514417.gif 1024w, /img/banner_Picadas_740x90_hu8335000798113607427.gif 2x" src="https://notaspampeanas.com/img/banner_Picadas_740x90_hu16658372186798142604.gif" alt="" /> </figure> </p> <div class="lead text-neutral-500 dark:text-neutral-400 !mb-9 text-xl"> Water deficit resistance in plants has long been a topic of interest for cultivating reliable crops. Some plants can alter their above-ground structure to lock in moisture, while others develop deep, industrious roots that find hard-to-reach water sources. While such responses are obvious to the naked eye, we know little about how responses to environmental stress occur at the microscopic, cellular level. </div> <p> <figure> <img class="my-0 rounded-md" loading="lazy" srcset=" /posts/1767106852444-sequia-plantas/featured_hu8610597036585170148.jpg 330w, /posts/1767106852444-sequia-plantas/featured_hu8554021835227462437.jpg 660w, /posts/1767106852444-sequia-plantas/featured_hu9569951474689404326.jpg 1024w, /posts/1767106852444-sequia-plantas/featured_hu14120633088912893644.jpg 2x" src="https://notaspampeanas.com/posts/1767106852444-sequia-plantas/featured_hu8554021835227462437.jpg" alt="Arabidopsis thaliana grown in the Dinneny lab. Image credit: Yue Rui" /> </figure> <strong>Arabidopsis thaliana grown in the Dinneny lab. Image credit: Yue Rui</strong></p>