In recent years sophisticated biomaterials have made a significant impact on our understanding of cellular behavior, particularly in the fields of stem cell research and tissue engineering. Nevertheless, the promising potential of stem cells for regenerative medicine has remained largely unmet. One reason for such limitations could be that there is still incomplete understanding of stem cell behavior due to a lack of advanced in vitro tools suitable to achieve adequate control over cellular processes. By mimicking the dynamic and complex biophysical and biochemical interactions between cells and their natural extracellular matrixes (ECMs), it is possible that we may bridge this gap between current limited in vitro models and complex in vivo organisms. In this thesis, an innovative class of biomaterials is presented that enables the flexible in vitro recapitulation of the dynamic biochemical and biophysical signaling involved in controlling cell fate. Such systems of increasing fidelity to real physiological processes could bring new insights into fundamental cell biology as well as bring us to closer towards cell-based therapeutics applications. In order to achieve a dynamic artificial ECM (aECM), we designed chemical schemes which would allow us to control the biochemical and biophysical properties of the hydrogel in space, time and intensity. The chosen concept is built on a synthetic hydrogel providing static physicochemical support, while spatiotemporal control over a single or multiple signals is achieved by spatiotemporal photoactivation reactions within this hydrogel. Indeed, by modulating the duration, location and intensity of illumination, desired heterogeneities in biochemical and biophysical signal can be introduced in the otherwise homogeneous and static hydrogel network. To implement the designed hydrogel photo-patterning tool, new chemical components were synthesized. Synthetic hydrogels based on poly (ethylene glycol) (PEG) were utilized due to their inert properties, cell biocompatibility and lack of unspecific protein binding. Biochemical signal tethering was rendered spatiotemporally controllable by adding photosensitivity to the existing enzyme-based crosslinking scheme. This was achieved by functionalizing one of enzymatic substrate with a photo-labile “caging” moiety, thereby preventing crosslinking to occur until light illumination. This caged substrate was incorporated into the hydrogel network and served as a light-controllable and specific ligand-binding site. Importantly, it was possible to photo-pattern proteins, which are much complex than peptide-based biomolecules, and their bioactivity was fully preserved with this site-specific immobilization scheme. It was also possible to pattern biophysical cues by making the Michael-type (MT) addition reaction for crosslinking PEG-based hydrogel photosensitive. In this case, the thiol moieties of one of the reactive PEG macromers undergoing crosslinking, were equipped with a caging group which prevented its susceptibility to the counter-reactive functionality, the vinyl sulfone group. Thus, the crosslinking density of the hydrogel backbone could be controlled by light, which was directly translated into differential patterns of hydrogel stiffness. Using this approach, user-defined biochemical and biophysical patterns and even gradients could be obtained in the spatiotemporal manner within the same hydrogel. The crosslinking reaction is the critical parameter in the success of hydrogel photo-patterning, and must rely on a well-controlled and highly selective chemical scheme. Therefore, we also developed a novel enzyme-based cross-linking scheme for synthetic PEG hydrogels. The reaction originates from the naturally occurring post-translational modification of proteins by phosphopantetheine (Ppant) group performed by a family of enzymes known as Ppant transferases (PPTases). By synthesizing biochemical components of this reaction, we implemented a PPTase-catalyzed reaction to form and bio-functionalize PEG hydrogel. The utility of the developed hydrogel platforms was determined in the context of 2D and 3D cell culture. Photo-directed patterns of a cell-adhesive fibronectin fragment triggered adhesion and spreading of muscle progenitor cells, a phenomenon which occurred only within the areas of patterned signaling protein. A photo-patterned elasticity gradient was used to direct mesenchymal stem cell spreading and migration. Finally, the PPTase-based hydrogel was proven to be suitable for 3D culture, as shown by encapsulation of primary human fibroblasts. In this thesis, we demonstrated that a combination of chemical schemes could be assembled to achieve a functional materials toolbox which would begin to reconstruct the complexity of the dynamic in vivo ECM. Such a tool is expected to contribute to the field of cell biology by allowing us to study questions which previously could not be addressed in vitro, and could ultimately contribute to cell-based regenerative medicine.