Valve train including engine braking system

What is claimed is: 1. A valve train arrangement comprising: at least one exhaust valve; a support arranged adjacent to the at least one exhaust valve and configured to engage a lobe defined on a camshaft, the support defining a cavity; a reverse-spring hydraulic lash adjuster (RSHLA) positioned within the cavity of the support, the RSHLA configured to adjust lash between the support and the at least one exhaust valve, and the RSHLA having a predetermined closing velocity; and an engine brake system configured to engage the at least one exhaust valve, such that: (i) upon activation of the engine brake system, the engine brake system engages the at least one exhaust valve to open the at least one exhaust valve; (ii) upon deactivation of the engine brake system, the engine brake system disengages the at least one exhaust valve such that the at least one exhaust valve is closed; wherein a deactivation velocity of the engine brake system is lower than the predetermined closing velocity of the RSHLA. 2. The valve train arrangement of claim 1 , wherein the RSHLA includes: an outer housing defining at least one hydraulic fluid passage; a plunger slidingly arranged within the outer housing; a return spring arranged between the outer housing and the plunger; a valve assembly having: a closing body configured to block an opening defining a connection between an upper chamber and lower chamber of the RSHLA, a retainer arranged between the plunger and the outer housing to hold the closing body, and a valve spring positioned between the opening and the closing body, the valve spring biasing the closing body to an open position. 3. The valve train arrangement of claim 2 , wherein the valve assembly is open and the closing body remains unseated from the opening during deactivation of the engine brake system. 4. The valve train arrangement of claim 2 , wherein the predetermined closing velocity of the RSHLA is determined based on a speed of a relative displacement between the plunger and the outer housing, wherein the closing body becomes seated to the opening during the relative displacement. 5. The valve train arrangement of claim 2 , wherein the predetermined closing velocity of the RSHLA is based on at least one of: viscosity of hydraulic fluid in the RSHLA; flow rate of hydraulic fluid in the RSHLA; clearance between the plunger and the outer housing; flow rate through orifices defined in the retainer; a relative distance between the retainer, the closing body, and the opening; a profile of an interface defined between the closing body and the opening; stiffness of the return spring; or stiffness of the valve spring. 6. The valve train arrangement of claim 1 , wherein the RSHLA is in an extended position after activation of the engine brake system. 7. The valve train arrangement of claim 6 , wherein the RSHLA moves from the extended position to a compressed position upon the engine brake system transitioning from activation to deactivation. 8. The valve train arrangement of claim 1 , wherein the support is a lifter. 9. The valve train arrangement of claim 1 , wherein the support is a rocker arm. 10. The valve train arrangement of claim 1 , wherein the support is a finger follower. 11. The valve train arrangement of claim 1 , wherein the at least one exhaust valve is supported in an exhaust valve bridge. 12. The valve train arrangement of claim 1 , wherein the engine brake system includes at least one of: an actuator or a lobed shaft. 13. A method of accommodating lash in a valve train including an engine braking system, the method comprising: arranging a reverse-spring hydraulic lash adjuster (RSHLA) between (i) a support engaging a lobe defined on a camshaft, and (ii) at least one exhaust valve; activating an engine brake system to drive the at least one exhaust valve to an open position, wherein the RSHLA expands to maintain contact with the support and the at least one exhaust valve; and deactivating the engine brake system such that the engine brake system disengages from the at least one exhaust valve, and the RSHLA compresses as the at least one exhaust valve returns to a closed position while the RSHLA maintains contact with the support and the at least one exhaust valve, wherein the RSHLA has a predetermined closing velocity and a deactivation velocity of the engine brake system is lower than the predetermined closing velocity of the RSHLA. 14. The method of claim 13 , wherein the RSHLA includes: an outer housing defining at least one hydraulic fluid passage; a plunger slidingly arranged within the outer housing; a return spring arranged between the outer housing and the plunger; a valve assembly having: a closing body configured to block an opening defining a connection between an upper chamber and lower chamber of the RSHLA, a retainer arranged between the plunger and the outer housing to hold the closing body, and a valve spring positioned between the opening and the closing body, the valve spring biasing the closing body to an open position. 15. The method of claim 14 , wherein the predetermined closing velocity of the RSHLA is based on at least one of: viscosity of hydraulic fluid in the RSHLA; flow rate of hydraulic fluid in the RSHLA; clearance between the plunger and the outer housing; flow rate through orifices defined in the retainer; a relative distance between the retainer, the closing body, and the opening; a profile of an interface defined between the closing body and the opening; stiffness of the return spring; or stiffness of the valve spring.